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-
-/* -----------------------------------------------------------------------------------------------------------
-Software License for The Fraunhofer FDK AAC Codec Library for Android
-
-© Copyright 1995 - 2013 Fraunhofer-Gesellschaft zur Förderung der angewandten Forschung e.V.
- All rights reserved.
-
- 1. INTRODUCTION
-The Fraunhofer FDK AAC Codec Library for Android ("FDK AAC Codec") is software that implements
-the MPEG Advanced Audio Coding ("AAC") encoding and decoding scheme for digital audio.
-This FDK AAC Codec software is intended to be used on a wide variety of Android devices.
-
-AAC's HE-AAC and HE-AAC v2 versions are regarded as today's most efficient general perceptual
-audio codecs. AAC-ELD is considered the best-performing full-bandwidth communications codec by
-independent studies and is widely deployed. AAC has been standardized by ISO and IEC as part
-of the MPEG specifications.
-
-Patent licenses for necessary patent claims for the FDK AAC Codec (including those of Fraunhofer)
-may be obtained through Via Licensing (www.vialicensing.com) or through the respective patent owners
-individually for the purpose of encoding or decoding bit streams in products that are compliant with
-the ISO/IEC MPEG audio standards. Please note that most manufacturers of Android devices already license
-these patent claims through Via Licensing or directly from the patent owners, and therefore FDK AAC Codec
-software may already be covered under those patent licenses when it is used for those licensed purposes only.
-
-Commercially-licensed AAC software libraries, including floating-point versions with enhanced sound quality,
-are also available from Fraunhofer. Users are encouraged to check the Fraunhofer website for additional
-applications information and documentation.
-
-2. COPYRIGHT LICENSE
-
-Redistribution and use in source and binary forms, with or without modification, are permitted without
-payment of copyright license fees provided that you satisfy the following conditions:
-
-You must retain the complete text of this software license in redistributions of the FDK AAC Codec or
-your modifications thereto in source code form.
-
-You must retain the complete text of this software license in the documentation and/or other materials
-provided with redistributions of the FDK AAC Codec or your modifications thereto in binary form.
-You must make available free of charge copies of the complete source code of the FDK AAC Codec and your
-modifications thereto to recipients of copies in binary form.
-
-The name of Fraunhofer may not be used to endorse or promote products derived from this library without
-prior written permission.
-
-You may not charge copyright license fees for anyone to use, copy or distribute the FDK AAC Codec
-software or your modifications thereto.
-
-Your modified versions of the FDK AAC Codec must carry prominent notices stating that you changed the software
-and the date of any change. For modified versions of the FDK AAC Codec, the term
-"Fraunhofer FDK AAC Codec Library for Android" must be replaced by the term
-"Third-Party Modified Version of the Fraunhofer FDK AAC Codec Library for Android."
-
-3. NO PATENT LICENSE
-
-NO EXPRESS OR IMPLIED LICENSES TO ANY PATENT CLAIMS, including without limitation the patents of Fraunhofer,
-ARE GRANTED BY THIS SOFTWARE LICENSE. Fraunhofer provides no warranty of patent non-infringement with
-respect to this software.
-
-You may use this FDK AAC Codec software or modifications thereto only for purposes that are authorized
-by appropriate patent licenses.
-
-4. DISCLAIMER
-
-This FDK AAC Codec software is provided by Fraunhofer on behalf of the copyright holders and contributors
-"AS IS" and WITHOUT ANY EXPRESS OR IMPLIED WARRANTIES, including but not limited to the implied warranties
-of merchantability and fitness for a particular purpose. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR
-CONTRIBUTORS BE LIABLE for any direct, indirect, incidental, special, exemplary, or consequential damages,
-including but not limited to procurement of substitute goods or services; loss of use, data, or profits,
-or business interruption, however caused and on any theory of liability, whether in contract, strict
-liability, or tort (including negligence), arising in any way out of the use of this software, even if
-advised of the possibility of such damage.
-
-5. CONTACT INFORMATION
-
-Fraunhofer Institute for Integrated Circuits IIS
-Attention: Audio and Multimedia Departments - FDK AAC LL
-Am Wolfsmantel 33
-91058 Erlangen, Germany
-
-www.iis.fraunhofer.de/amm
-amm-info@iis.fraunhofer.de
------------------------------------------------------------------------------------------------------------ */
-
-/******************************** MPEG Audio Encoder **************************
-
- Initial author: M. Werner
- contents/description: Threshold compensation
-
-******************************************************************************/
-
-#include "common_fix.h"
-
-#include "adj_thr_data.h"
-#include "adj_thr.h"
-#include "qc_data.h"
-#include "sf_estim.h"
-#include "aacEnc_ram.h"
-
-
-
-
-#define INV_INT_TAB_SIZE (8)
-static const FIXP_DBL invInt[INV_INT_TAB_SIZE] =
-{
- 0x7fffffff, 0x7fffffff, 0x40000000, 0x2aaaaaaa, 0x20000000, 0x19999999, 0x15555555, 0x12492492
-};
-
-
-#define INV_SQRT4_TAB_SIZE (8)
-static const FIXP_DBL invSqrt4[INV_SQRT4_TAB_SIZE] =
-{
- 0x7fffffff, 0x7fffffff, 0x6ba27e65, 0x61424bb5, 0x5a827999, 0x55994845, 0x51c8e33c, 0x4eb160d1
-};
-
-
-/*static const INT invRedExp = 4;*/
-static const FIXP_DBL SnrLdMin1 = (FIXP_DBL)0xfcad0ddf; /*FL2FXCONST_DBL(FDKlog(0.316)/FDKlog(2.0)/LD_DATA_SCALING);*/
-static const FIXP_DBL SnrLdMin2 = (FIXP_DBL)0x0351e1a2; /*FL2FXCONST_DBL(FDKlog(3.16) /FDKlog(2.0)/LD_DATA_SCALING);*/
-static const FIXP_DBL SnrLdFac = (FIXP_DBL)0xff5b2c3e; /*FL2FXCONST_DBL(FDKlog(0.8) /FDKlog(2.0)/LD_DATA_SCALING);*/
-
-static const FIXP_DBL SnrLdMin3 = (FIXP_DBL)0xfe000000; /*FL2FXCONST_DBL(FDKlog(0.5) /FDKlog(2.0)/LD_DATA_SCALING);*/
-static const FIXP_DBL SnrLdMin4 = (FIXP_DBL)0x02000000; /*FL2FXCONST_DBL(FDKlog(2.0) /FDKlog(2.0)/LD_DATA_SCALING);*/
-static const FIXP_DBL SnrLdMin5 = (FIXP_DBL)0xfc000000; /*FL2FXCONST_DBL(FDKlog(0.25) /FDKlog(2.0)/LD_DATA_SCALING);*/
-
-
-/*
-The bits2Pe factors are choosen for the case that some times
-the crash recovery strategy will be activated once.
-*/
-
-typedef struct {
- INT bitrate;
- LONG bits2PeFactor_mono;
- LONG bits2PeFactor_mono_slope;
- LONG bits2PeFactor_stereo;
- LONG bits2PeFactor_stereo_slope;
- LONG bits2PeFactor_mono_scfOpt;
- LONG bits2PeFactor_mono_scfOpt_slope;
- LONG bits2PeFactor_stereo_scfOpt;
- LONG bits2PeFactor_stereo_scfOpt_slope;
-
-} BIT_PE_SFAC;
-
-typedef struct {
- const INT sampleRate;
- const BIT_PE_SFAC * pPeTab;
- const INT nEntries;
-
-} BITS2PE_CFG_TAB;
-
-static const BIT_PE_SFAC S_Bits2PeTab16000[] = {
- { 10000, 0x228F5C29, 0x02FEF55D, 0x1D70A3D7, 0x09BC9D6D, 0x228F5C29, 0x02FEF55D, 0x1C28F5C3, 0x0CBB92CA},
- { 24000, 0x23D70A3D, 0x029F16B1, 0x2199999A, 0x07DD4413, 0x23D70A3D, 0x029F16B1, 0x2199999A, 0x07DD4413},
- { 32000, 0x247AE148, 0x11B1D92B, 0x23851EB8, 0x01F75105, 0x247AE148, 0x110A137F, 0x23851EB8, 0x01F75105},
- { 48000, 0x2D1EB852, 0x6833C600, 0x247AE148, 0x014F8B59, 0x2CCCCCCD, 0x68DB8BAC, 0x247AE148, 0x01F75105},
- { 64000, 0x60000000, 0x00000000, 0x251EB852, 0x154C985F, 0x60000000, 0x00000000, 0x2570A3D7, 0x154C985F},
- { 96000, 0x60000000, 0x00000000, 0x39EB851F, 0x088509C0, 0x60000000, 0x00000000, 0x3A3D70A4, 0x088509C0},
- {128000, 0x60000000, 0x00000000, 0x423D70A4, 0x18A43BB4, 0x60000000, 0x00000000, 0x428F5C29, 0x181E03F7},
- {148000, 0x60000000, 0x00000000, 0x5147AE14, 0x00000000, 0x60000000, 0x00000000, 0x5147AE14, 0x00000000}
-};
-
-static const BIT_PE_SFAC S_Bits2PeTab22050[] = {
- { 16000, 0x1a8f5c29, 0x1797cc3a, 0x128f5c29, 0x18e75793, 0x175c28f6, 0x221426fe, 0x00000000, 0x5a708ede},
- { 24000, 0x2051eb85, 0x092ccf6c, 0x18a3d70a, 0x13a92a30, 0x1fae147b, 0xbcbe61d, 0x16147ae1, 0x18e75793},
- { 32000, 0x228f5c29, 0x029f16b1, 0x1d70a3d7, 0x088509c0, 0x228f5c29, 0x29f16b1, 0x1c28f5c3, 0x0b242071},
- { 48000, 0x23d70a3d, 0x014f8b59, 0x2199999a, 0x03eea20a, 0x23d70a3d, 0x14f8b59, 0x2199999a, 0x03eea20a},
- { 64000, 0x247ae148, 0x08d8ec96, 0x23851eb8, 0x00fba882, 0x247ae148, 0x88509c0, 0x23851eb8, 0x00fba882},
- { 96000, 0x2d1eb852, 0x3419e300, 0x247ae148, 0x00a7c5ac, 0x2ccccccd, 0x346dc5d6, 0x247ae148, 0x00fba882},
- {128000, 0x60000000, 0x00000000, 0x251eb852, 0x029f16b1, 0x60000000, 0x00000000, 0x2570a3d7, 0x009f16b1},
- {148000, 0x60000000, 0x00000000, 0x26b851ec, 0x00000000, 0x60000000, 0x00000000, 0x270a3d71, 0x00000000}
-};
-
-static const BIT_PE_SFAC S_Bits2PeTab24000[] = {
- { 16000, 0x19eb851f, 0x13a92a30, 0x1147ae14, 0x164840e1, 0x1999999a, 0x12599ed8, 0x00000000, 0x46c764ae},
- { 24000, 0x1eb851ec, 0x0d1b7176, 0x16b851ec, 0x18e75793, 0x1e147ae1, 0x0fba8827, 0x1147ae14, 0x2c9081c3},
- { 32000, 0x21eb851f, 0x049667b6, 0x1ccccccd, 0x07357e67, 0x21eb851f, 0x03eea20a, 0x1c28f5c3, 0x07357e67},
- { 48000, 0x2428f5c3, 0x014f8b59, 0x2051eb85, 0x053e2d62, 0x23d70a3d, 0x01f75105, 0x1fae147b, 0x07357e67},
- { 64000, 0x24cccccd, 0x05e5f30e, 0x22e147ae, 0x01a36e2f, 0x24cccccd, 0x05e5f30e, 0x23333333, 0x014f8b59},
- { 96000, 0x2a8f5c29, 0x24b33db0, 0x247ae148, 0x00fba882, 0x2a8f5c29, 0x26fe718b, 0x247ae148, 0x00fba882},
- {128000, 0x4e666666, 0x1cd5f99c, 0x2570a3d7, 0x010c6f7a, 0x50a3d70a, 0x192a7371, 0x2570a3d7, 0x010c6f7a},
- {148000, 0x60000000, 0x00000000, 0x26147ae1, 0x00000000, 0x60000000, 0x00000000, 0x26147ae1, 0x00000000}
-};
-
-static const BIT_PE_SFAC S_Bits2PeTab32000[] = {
- { 16000, 0x1199999a, 0x20c49ba6, 0x00000000, 0x4577d955, 0x00000000, 0x60fe4799, 0x00000000, 0x00000000},
- { 24000, 0x1999999a, 0x0fba8827, 0x10f5c28f, 0x1b866e44, 0x17ae147b, 0x0fba8827, 0x00000000, 0x4d551d69},
- { 32000, 0x1d70a3d7, 0x07357e67, 0x17ae147b, 0x09d49518, 0x1b851eb8, 0x0a7c5ac4, 0x12e147ae, 0x110a137f},
- { 48000, 0x20f5c28f, 0x049667b6, 0x1c7ae148, 0x053e2d62, 0x20a3d70a, 0x053e2d62, 0x1b333333, 0x05e5f30e},
- { 64000, 0x23333333, 0x029f16b1, 0x1f0a3d71, 0x02f2f987, 0x23333333, 0x029f16b1, 0x1e147ae1, 0x03eea20a},
- { 96000, 0x25c28f5c, 0x2c3c9eed, 0x21eb851f, 0x01f75105, 0x25c28f5c, 0x0a7c5ac4, 0x21eb851f, 0x01a36e2f},
- {128000, 0x50f5c28f, 0x18a43bb4, 0x23d70a3d, 0x010c6f7a, 0x30000000, 0x168b5cc0, 0x23851eb8, 0x0192a737},
- {148000, 0x60000000, 0x00000000, 0x247ae148, 0x00dfb23b, 0x3dc28f5c, 0x300f4aaf, 0x247ae148, 0x01bf6476},
- {160000, 0x60000000, 0xb15b5740, 0x24cccccd, 0x053e2d62, 0x4f5c28f6, 0xbefd0072, 0x251eb852, 0x04fb1184},
- {200000, 0x00000000, 0x00000000, 0x2b333333, 0x0836be91, 0x00000000, 0x00000000, 0x2b333333, 0x0890390f},
- {320000, 0x00000000, 0x00000000, 0x4947ae14, 0x00000000, 0x00000000, 0x00000000, 0x4a8f5c29, 0x00000000}
-};
-
-static const BIT_PE_SFAC S_Bits2PeTab44100[] = {
- { 16000, 0x10a3d70a, 0x1797cc3a, 0x00000000, 0x00000000, 0x00000000, 0x59210386, 0x00000000, 0x00000000},
- { 24000, 0x16666666, 0x1797cc3a, 0x00000000, 0x639d5e4a, 0x15c28f5c, 0x12599ed8, 0x00000000, 0x5bc01a37},
- { 32000, 0x1c28f5c3, 0x049667b6, 0x1851eb85, 0x049667b6, 0x1a3d70a4, 0x088509c0, 0x16666666, 0x053e2d62},
- { 48000, 0x1e666666, 0x05e5f30e, 0x1a8f5c29, 0x049667b6, 0x1e666666, 0x05e5f30e, 0x18f5c28f, 0x05e5f30e},
- { 64000, 0x2147ae14, 0x0346dc5d, 0x1ccccccd, 0x02f2f987, 0x2147ae14, 0x02f2f987, 0x1bd70a3d, 0x039abf34},
- { 96000, 0x247ae148, 0x068db8bb, 0x1fae147b, 0x029f16b1, 0x2428f5c3, 0x0639d5e5, 0x1f5c28f6, 0x029f16b1},
- {128000, 0x2ae147ae, 0x1b435265, 0x223d70a4, 0x0192a737, 0x2a3d70a4, 0x1040bfe4, 0x21eb851f, 0x0192a737},
- {148000, 0x3b851eb8, 0x2832069c, 0x23333333, 0x00dfb23b, 0x3428f5c3, 0x2054c288, 0x22e147ae, 0x00dfb23b},
- {160000, 0x4a3d70a4, 0xc32ebe5a, 0x23851eb8, 0x01d5c316, 0x40000000, 0xcb923a2b, 0x23333333, 0x01d5c316},
- {200000, 0x00000000, 0x00000000, 0x25c28f5c, 0x0713f078, 0x00000000, 0x00000000, 0x2570a3d7, 0x072a4f17},
- {320000, 0x00000000, 0x00000000, 0x3fae147b, 0x00000000, 0x00000000, 0x00000000, 0x3fae147b, 0x00000000}
-};
-
-static const BIT_PE_SFAC S_Bits2PeTab48000[] = {
- { 16000, 0x0f5c28f6, 0x31ceaf25, 0x00000000, 0x00000000, 0x00000000, 0x74a771c9, 0x00000000, 0x00000000},
- { 24000, 0x1b851eb8, 0x029f16b1, 0x00000000, 0x663c74fb, 0x1c7ae148, 0xe47991bd, 0x00000000, 0x49667b5f},
- { 32000, 0x1c28f5c3, 0x029f16b1, 0x18f5c28f, 0x07357e67, 0x15c28f5c, 0x0f12c27a, 0x11eb851f, 0x13016484},
- { 48000, 0x1d70a3d7, 0x053e2d62, 0x1c7ae148, 0xfe08aefc, 0x1d1eb852, 0x068db8bb, 0x1b333333, 0xfeb074a8},
- { 64000, 0x20000000, 0x03eea20a, 0x1b851eb8, 0x0346dc5d, 0x2051eb85, 0x0346dc5d, 0x1a8f5c29, 0x039abf34},
- { 96000, 0x23d70a3d, 0x053e2d62, 0x1eb851ec, 0x029f16b1, 0x23851eb8, 0x04ea4a8c, 0x1e147ae1, 0x02f2f987},
- {128000, 0x28f5c28f, 0x14727dcc, 0x2147ae14, 0x0218def4, 0x2851eb85, 0x0e27e0f0, 0x20f5c28f, 0x0218def4},
- {148000, 0x3570a3d7, 0x1cd5f99c, 0x228f5c29, 0x01bf6476, 0x30f5c28f, 0x18777e75, 0x223d70a4, 0x01bf6476},
- {160000, 0x40000000, 0xcb923a2b, 0x23333333, 0x0192a737, 0x39eb851f, 0xd08d4bae, 0x22e147ae, 0x0192a737},
- {200000, 0x00000000, 0x00000000, 0x251eb852, 0x06775a1b, 0x00000000, 0x00000000, 0x24cccccd, 0x06a4175a},
- {320000, 0x00000000, 0x00000000, 0x3ccccccd, 0x00000000, 0x00000000, 0x00000000, 0x3d1eb852, 0x00000000}
-};
-
-static const BITS2PE_CFG_TAB bits2PeConfigTab[] = {
- { 16000, S_Bits2PeTab16000, sizeof(S_Bits2PeTab16000)/sizeof(BIT_PE_SFAC) },
- { 22050, S_Bits2PeTab22050, sizeof(S_Bits2PeTab22050)/sizeof(BIT_PE_SFAC) },
- { 24000, S_Bits2PeTab24000, sizeof(S_Bits2PeTab24000)/sizeof(BIT_PE_SFAC) },
- { 32000, S_Bits2PeTab32000, sizeof(S_Bits2PeTab32000)/sizeof(BIT_PE_SFAC) },
- { 44100, S_Bits2PeTab44100, sizeof(S_Bits2PeTab44100)/sizeof(BIT_PE_SFAC) },
- { 48000, S_Bits2PeTab48000, sizeof(S_Bits2PeTab48000)/sizeof(BIT_PE_SFAC) }
-};
-
-
-
-/* values for avoid hole flag */
-enum _avoid_hole_state {
- NO_AH =0,
- AH_INACTIVE =1,
- AH_ACTIVE =2
-};
-
-
-/* Q format definitions */
-#define Q_BITFAC (24) /* Q scaling used in FDKaacEnc_bitresCalcBitFac() calculation */
-#define Q_AVGBITS (17) /* scale bit values */
-
-
-/*****************************************************************************
- functionname: FDKaacEnc_InitBits2PeFactor
- description: retrieve bits2PeFactor from table
-*****************************************************************************/
-static void FDKaacEnc_InitBits2PeFactor(
- FIXP_DBL *bits2PeFactor_m,
- INT *bits2PeFactor_e,
- const INT bitRate,
- const INT nChannels,
- const INT sampleRate,
- const INT advancedBitsToPe,
- const INT invQuant
- )
-{
- /* default bits2pe factor */
- FIXP_DBL bit2PE_m = FL2FXCONST_DBL(1.18f/(1<<(1)));
- INT bit2PE_e = 1;
-
- /* make use of advanced bits to pe factor table */
- if (advancedBitsToPe) {
-
- int i;
- const BIT_PE_SFAC *peTab = NULL;
- INT size = 0;
-
-
- /* Get correct table entry */
- for (i=0; i<(INT)(sizeof(bits2PeConfigTab)/sizeof(BITS2PE_CFG_TAB)); i++) {
- if (sampleRate >= bits2PeConfigTab[i].sampleRate) {
- peTab = bits2PeConfigTab[i].pPeTab;
- size = bits2PeConfigTab[i].nEntries;
- }
- }
-
- if ( (peTab!=NULL) && (size!=0) ) {
-
- INT startB = -1;
- LONG startPF = 0;
- LONG peSlope = 0;
-
- /* stereo or mono mode and invQuant used or not */
- for (i=0; i<size-1; i++)
- {
- if ((peTab[i].bitrate<=bitRate) && ((peTab[i+1].bitrate>bitRate) || ((i==size-2)) ))
- {
- if (nChannels==1)
- {
- startPF = (!invQuant) ? peTab[i].bits2PeFactor_mono : peTab[i].bits2PeFactor_mono_scfOpt;
- peSlope = (!invQuant) ? peTab[i].bits2PeFactor_mono_slope : peTab[i].bits2PeFactor_mono_scfOpt_slope;
- /*endPF = (!invQuant) ? peTab[i+1].bits2PeFactor_mono : peTab[i+1].bits2PeFactor_mono_scfOpt;
- endB=peTab[i+1].bitrate;*/
- startB=peTab[i].bitrate;
- break;
- }
- else
- {
- startPF = (!invQuant) ? peTab[i].bits2PeFactor_stereo : peTab[i].bits2PeFactor_stereo_scfOpt;
- peSlope = (!invQuant) ? peTab[i].bits2PeFactor_stereo_slope : peTab[i].bits2PeFactor_stereo_scfOpt_slope;
- /*endPF = (!invQuant) ? peTab[i+1].bits2PeFactor_stereo : peTab[i+1].bits2PeFactor_stereo_scfOpt;
- endB=peTab[i+1].bitrate;*/
- startB=peTab[i].bitrate;
- break;
- }
- }
- } /* for i */
-
- /* if a configuration is available */
- if (startB!=-1) {
- /* linear interpolate to actual PEfactor */
- FIXP_DBL peFac = fMult((FIXP_DBL)(bitRate-startB)<<14, (FIXP_DBL)peSlope) << 2;
- FIXP_DBL bit2PE = peFac + (FIXP_DBL)startPF; /* startPF_float = startPF << 2 */
-
- /* sanity check if bits2pe value is high enough */
- if ( bit2PE >= (FL2FXCONST_DBL(0.35f) >> 2) ) {
- bit2PE_m = bit2PE;
- bit2PE_e = 2; /* table is fixed scaled */
- }
- } /* br */
- } /* sr */
- } /* advancedBitsToPe */
-
-
- /* return bits2pe factor */
- *bits2PeFactor_m = bit2PE_m;
- *bits2PeFactor_e = bit2PE_e;
-}
-
-
-/*****************************************************************************
-functionname: FDKaacEnc_bits2pe2
-description: convert from bits to pe
-*****************************************************************************/
-static INT FDKaacEnc_bits2pe2(
- const INT bits,
- const FIXP_DBL factor_m,
- const INT factor_e
- )
-{
- return (INT)(fMult(factor_m, (FIXP_DBL)(bits<<Q_AVGBITS)) >> (Q_AVGBITS-factor_e));
-}
-
-/*****************************************************************************
-functionname: FDKaacEnc_calcThreshExp
-description: loudness calculation (threshold to the power of redExp)
-*****************************************************************************/
-static void FDKaacEnc_calcThreshExp(FIXP_DBL thrExp[(2)][MAX_GROUPED_SFB],
- QC_OUT_CHANNEL* qcOutChannel[(2)],
- PSY_OUT_CHANNEL* psyOutChannel[(2)],
- const INT nChannels)
-{
- INT ch, sfb, sfbGrp;
- FIXP_DBL thrExpLdData;
-
- for (ch=0; ch<nChannels; ch++) {
- for(sfbGrp = 0;sfbGrp < psyOutChannel[ch]->sfbCnt;sfbGrp+= psyOutChannel[ch]->sfbPerGroup) {
- for (sfb=0; sfb<psyOutChannel[ch]->maxSfbPerGroup; sfb++) {
- thrExpLdData = psyOutChannel[ch]->sfbThresholdLdData[sfbGrp+sfb]>>2 ;
- thrExp[ch][sfbGrp+sfb] = CalcInvLdData(thrExpLdData);
- }
- }
- }
-}
-
-
-/*****************************************************************************
- functionname: FDKaacEnc_adaptMinSnr
- description: reduce minSnr requirements for bands with relative low energies
-*****************************************************************************/
-static void FDKaacEnc_adaptMinSnr(QC_OUT_CHANNEL *qcOutChannel[(2)],
- PSY_OUT_CHANNEL *psyOutChannel[(2)],
- MINSNR_ADAPT_PARAM *msaParam,
- const INT nChannels)
-{
- INT ch, sfb, sfbGrp, nSfb;
- FIXP_DBL avgEnLD64, dbRatio, minSnrRed;
- FIXP_DBL minSnrLimitLD64 = FL2FXCONST_DBL(-0.00503012648262f); /* ld64(0.8f) */
- FIXP_DBL nSfbLD64;
- FIXP_DBL accu;
-
- for (ch=0; ch<nChannels; ch++) {
- /* calc average energy per scalefactor band */
- nSfb = 0;
- accu = FL2FXCONST_DBL(0.0f);
-
- for (sfbGrp=0; sfbGrp < psyOutChannel[ch]->sfbCnt; sfbGrp+=psyOutChannel[ch]->sfbPerGroup) {
- for (sfb=0; sfb<psyOutChannel[ch]->maxSfbPerGroup; sfb++) {
- accu += psyOutChannel[ch]->sfbEnergy[sfbGrp+sfb]>>6;
- nSfb++;
- }
- }
-
- if ((accu == FL2FXCONST_DBL(0.0f)) || (nSfb == 0)) {
- avgEnLD64 = FL2FXCONST_DBL(-1.0f);
- }
- else {
- nSfbLD64 = CalcLdInt(nSfb);
- avgEnLD64 = CalcLdData(accu);
- avgEnLD64 = avgEnLD64 + FL2FXCONST_DBL(0.09375f) - nSfbLD64; /* 0.09375f: compensate shift with 6 */
- }
-
- /* reduce minSnr requirement by minSnr^minSnrRed dependent on avgEn/sfbEn */
- for (sfbGrp=0; sfbGrp < psyOutChannel[ch]->sfbCnt; sfbGrp+=psyOutChannel[ch]->sfbPerGroup) {
- for (sfb=0; sfb<psyOutChannel[ch]->maxSfbPerGroup; sfb++) {
- if ( (msaParam->startRatio + qcOutChannel[ch]->sfbEnergyLdData[sfbGrp+sfb]) < avgEnLD64 ) {
- dbRatio = fMult((avgEnLD64 - qcOutChannel[ch]->sfbEnergyLdData[sfbGrp+sfb]),FL2FXCONST_DBL(0.3010299956f)); /* scaled by (1.0f/(10.0f*64.0f)) */
- minSnrRed = msaParam->redOffs + fMult(msaParam->redRatioFac,dbRatio); /* scaled by 1.0f/64.0f*/
- minSnrRed = fixMax(minSnrRed, msaParam->maxRed); /* scaled by 1.0f/64.0f*/
- qcOutChannel[ch]->sfbMinSnrLdData[sfbGrp+sfb] = (fMult(qcOutChannel[ch]->sfbMinSnrLdData[sfbGrp+sfb],minSnrRed)) << 6;
- qcOutChannel[ch]->sfbMinSnrLdData[sfbGrp+sfb] = fixMin(minSnrLimitLD64, qcOutChannel[ch]->sfbMinSnrLdData[sfbGrp+sfb]);
- }
- }
- }
- }
-}
-
-
-/*****************************************************************************
-functionname: FDKaacEnc_initAvoidHoleFlag
-description: determine bands where avoid hole is not necessary resp. possible
-*****************************************************************************/
-static void FDKaacEnc_initAvoidHoleFlag(QC_OUT_CHANNEL *qcOutChannel[(2)],
- PSY_OUT_CHANNEL *psyOutChannel[(2)],
- UCHAR ahFlag[(2)][MAX_GROUPED_SFB],
- struct TOOLSINFO *toolsInfo,
- const INT nChannels,
- const PE_DATA *peData,
- AH_PARAM *ahParam)
-{
- INT ch, sfb, sfbGrp;
- FIXP_DBL sfbEn, sfbEnm1;
- FIXP_DBL sfbEnLdData;
- FIXP_DBL avgEnLdData;
-
- /* decrease spread energy by 3dB for long blocks, resp. 2dB for shorts
- (avoid more holes in long blocks) */
- for (ch=0; ch<nChannels; ch++) {
- INT sfbGrp, sfb;
- QC_OUT_CHANNEL* qcOutChan = qcOutChannel[ch];
-
- if (psyOutChannel[ch]->lastWindowSequence != SHORT_WINDOW) {
- for (sfbGrp = 0;sfbGrp < psyOutChannel[ch]->sfbCnt;sfbGrp+= psyOutChannel[ch]->sfbPerGroup)
- for (sfb=0; sfb<psyOutChannel[ch]->maxSfbPerGroup; sfb++)
- qcOutChan->sfbSpreadEnergy[sfbGrp+sfb] >>= 1 ;
- }
- else {
- for (sfbGrp = 0;sfbGrp < psyOutChannel[ch]->sfbCnt;sfbGrp+= psyOutChannel[ch]->sfbPerGroup)
- for (sfb=0; sfb<psyOutChannel[ch]->maxSfbPerGroup; sfb++)
- qcOutChan->sfbSpreadEnergy[sfbGrp+sfb] =
- fMult(FL2FXCONST_DBL(0.63f),
- qcOutChan->sfbSpreadEnergy[sfbGrp+sfb]) ;
- }
- }
-
- /* increase minSnr for local peaks, decrease it for valleys */
- if (ahParam->modifyMinSnr) {
- for(ch=0; ch<nChannels; ch++) {
- QC_OUT_CHANNEL* qcOutChan = qcOutChannel[ch];
- for(sfbGrp = 0;sfbGrp < psyOutChannel[ch]->sfbCnt;sfbGrp+= psyOutChannel[ch]->sfbPerGroup){
- for (sfb=0; sfb<psyOutChannel[ch]->maxSfbPerGroup; sfb++) {
- FIXP_DBL sfbEnp1, avgEn;
- if (sfb > 0)
- sfbEnm1 = qcOutChan->sfbEnergy[sfbGrp+sfb-1];
- else
- sfbEnm1 = qcOutChan->sfbEnergy[sfbGrp+sfb];
-
- if (sfb < psyOutChannel[ch]->maxSfbPerGroup-1)
- sfbEnp1 = qcOutChan->sfbEnergy[sfbGrp+sfb+1];
- else
- sfbEnp1 = qcOutChan->sfbEnergy[sfbGrp+sfb];
-
- avgEn = (sfbEnm1>>1) + (sfbEnp1>>1);
- avgEnLdData = CalcLdData(avgEn);
- sfbEn = qcOutChan->sfbEnergy[sfbGrp+sfb];
- sfbEnLdData = qcOutChan->sfbEnergyLdData[sfbGrp+sfb];
- /* peak ? */
- if (sfbEn > avgEn) {
- FIXP_DBL tmpMinSnrLdData;
- if (psyOutChannel[ch]->lastWindowSequence==LONG_WINDOW)
- tmpMinSnrLdData = fixMax( SnrLdFac + (FIXP_DBL)(avgEnLdData - sfbEnLdData), (FIXP_DBL)SnrLdMin1 ) ;
- else
- tmpMinSnrLdData = fixMax( SnrLdFac + (FIXP_DBL)(avgEnLdData - sfbEnLdData), (FIXP_DBL)SnrLdMin3 ) ;
-
- qcOutChan->sfbMinSnrLdData[sfbGrp+sfb] =
- fixMin(qcOutChan->sfbMinSnrLdData[sfbGrp+sfb], tmpMinSnrLdData);
- }
- /* valley ? */
- if ( ((sfbEnLdData+(FIXP_DBL)SnrLdMin4) < (FIXP_DBL)avgEnLdData) && (sfbEn > FL2FXCONST_DBL(0.0)) ) {
- FIXP_DBL tmpMinSnrLdData = avgEnLdData - sfbEnLdData -(FIXP_DBL)SnrLdMin4 + qcOutChan->sfbMinSnrLdData[sfbGrp+sfb];
- tmpMinSnrLdData = fixMin((FIXP_DBL)SnrLdFac, tmpMinSnrLdData);
- qcOutChan->sfbMinSnrLdData[sfbGrp+sfb] = fixMin(tmpMinSnrLdData,
- (FIXP_DBL)(qcOutChan->sfbMinSnrLdData[sfbGrp+sfb] + SnrLdMin2 ));
- }
- }
- }
- }
- }
-
- /* stereo: adapt the minimum requirements sfbMinSnr of mid and
- side channels to avoid spending unnoticable bits */
- if (nChannels == 2) {
- QC_OUT_CHANNEL* qcOutChanM = qcOutChannel[0];
- QC_OUT_CHANNEL* qcOutChanS = qcOutChannel[1];
- PSY_OUT_CHANNEL* psyOutChanM = psyOutChannel[0];
- for(sfbGrp = 0;sfbGrp < psyOutChanM->sfbCnt;sfbGrp+= psyOutChanM->sfbPerGroup){
- for (sfb=0; sfb<psyOutChanM->maxSfbPerGroup; sfb++) {
- if (toolsInfo->msMask[sfbGrp+sfb]) {
- FIXP_DBL maxSfbEnLd = fixMax(qcOutChanM->sfbEnergyLdData[sfbGrp+sfb],qcOutChanS->sfbEnergyLdData[sfbGrp+sfb]);
- FIXP_DBL maxThrLd, sfbMinSnrTmpLd;
-
- if ( ((SnrLdMin5>>1) + (maxSfbEnLd>>1) + (qcOutChanM->sfbMinSnrLdData[sfbGrp+sfb]>>1)) <= FL2FXCONST_DBL(-0.5f))
- maxThrLd = FL2FXCONST_DBL(-1.0f) ;
- else
- maxThrLd = SnrLdMin5 + maxSfbEnLd + qcOutChanM->sfbMinSnrLdData[sfbGrp+sfb];
-
- if (qcOutChanM->sfbEnergy[sfbGrp+sfb] > FL2FXCONST_DBL(0.0f))
- sfbMinSnrTmpLd = maxThrLd - qcOutChanM->sfbEnergyLdData[sfbGrp+sfb];
- else
- sfbMinSnrTmpLd = FL2FXCONST_DBL(0.0f);
-
- qcOutChanM->sfbMinSnrLdData[sfbGrp+sfb] = fixMax(qcOutChanM->sfbMinSnrLdData[sfbGrp+sfb],sfbMinSnrTmpLd);
-
- if (qcOutChanM->sfbMinSnrLdData[sfbGrp+sfb] <= FL2FXCONST_DBL(0.0f))
- qcOutChanM->sfbMinSnrLdData[sfbGrp+sfb] = fixMin(qcOutChanM->sfbMinSnrLdData[sfbGrp+sfb], (FIXP_DBL)SnrLdFac);
-
- if (qcOutChanS->sfbEnergy[sfbGrp+sfb] > FL2FXCONST_DBL(0.0f))
- sfbMinSnrTmpLd = maxThrLd - qcOutChanS->sfbEnergyLdData[sfbGrp+sfb];
- else
- sfbMinSnrTmpLd = FL2FXCONST_DBL(0.0f);
-
- qcOutChanS->sfbMinSnrLdData[sfbGrp+sfb] = fixMax(qcOutChanS->sfbMinSnrLdData[sfbGrp+sfb],sfbMinSnrTmpLd);
-
- if (qcOutChanS->sfbMinSnrLdData[sfbGrp+sfb] <= FL2FXCONST_DBL(0.0f))
- qcOutChanS->sfbMinSnrLdData[sfbGrp+sfb] = fixMin(qcOutChanS->sfbMinSnrLdData[sfbGrp+sfb],(FIXP_DBL)SnrLdFac);
-
- if (qcOutChanM->sfbEnergy[sfbGrp+sfb]>qcOutChanM->sfbSpreadEnergy[sfbGrp+sfb])
- qcOutChanS->sfbSpreadEnergy[sfbGrp+sfb] =
- fMult(qcOutChanS->sfbEnergy[sfbGrp+sfb], FL2FXCONST_DBL(0.9f));
-
- if (qcOutChanS->sfbEnergy[sfbGrp+sfb]>qcOutChanS->sfbSpreadEnergy[sfbGrp+sfb])
- qcOutChanM->sfbSpreadEnergy[sfbGrp+sfb] =
- fMult(qcOutChanM->sfbEnergy[sfbGrp+sfb], FL2FXCONST_DBL(0.9f));
- }
- }
- }
- }
-
- /* init ahFlag (0: no ah necessary, 1: ah possible, 2: ah active */
- for(ch=0; ch<nChannels; ch++) {
- QC_OUT_CHANNEL *qcOutChan = qcOutChannel[ch];
- PSY_OUT_CHANNEL *psyOutChan = psyOutChannel[ch];
- for(sfbGrp = 0;sfbGrp < psyOutChan->sfbCnt;sfbGrp+= psyOutChan->sfbPerGroup){
- for (sfb=0; sfb<psyOutChan->maxSfbPerGroup; sfb++) {
- if ((qcOutChan->sfbSpreadEnergy[sfbGrp+sfb] > qcOutChan->sfbEnergy[sfbGrp+sfb])
- || (qcOutChan->sfbMinSnrLdData[sfbGrp+sfb] > FL2FXCONST_DBL(0.0f))) {
- ahFlag[ch][sfbGrp+sfb] = NO_AH;
- }
- else {
- ahFlag[ch][sfbGrp+sfb] = AH_INACTIVE;
- }
- }
- }
- }
-}
-
-
-
-/**
- * \brief Calculate constants that do not change during successive pe calculations.
- *
- * \param peData Pointer to structure containing PE data of current element.
- * \param psyOutChannel Pointer to PSY_OUT_CHANNEL struct holding nChannels elements.
- * \param qcOutChannel Pointer to QC_OUT_CHANNEL struct holding nChannels elements.
- * \param nChannels Number of channels in element.
- * \param peOffset Fixed PE offset defined while FDKaacEnc_AdjThrInit() depending on bitrate.
- *
- * \return void
- */
-static
-void FDKaacEnc_preparePe(PE_DATA *peData,
- PSY_OUT_CHANNEL* psyOutChannel[(2)],
- QC_OUT_CHANNEL* qcOutChannel[(2)],
- const INT nChannels,
- const INT peOffset)
-{
- INT ch;
-
- for(ch=0; ch<nChannels; ch++) {
- PSY_OUT_CHANNEL *psyOutChan = psyOutChannel[ch];
- FDKaacEnc_prepareSfbPe(&peData->peChannelData[ch],
- psyOutChan->sfbEnergyLdData,
- psyOutChan->sfbThresholdLdData,
- qcOutChannel[ch]->sfbFormFactorLdData,
- psyOutChan->sfbOffsets,
- psyOutChan->sfbCnt,
- psyOutChan->sfbPerGroup,
- psyOutChan->maxSfbPerGroup);
- }
- peData->offset = peOffset;
-}
-
-/**
- * \brief Calculate weighting factor for threshold adjustment.
- *
- * Calculate weighting factor to be applied at energies and thresholds in ld64 format.
- *
- * \param peData, Pointer to PE data in current element.
- * \param psyOutChannel Pointer to PSY_OUT_CHANNEL struct holding nChannels elements.
- * \param qcOutChannel Pointer to QC_OUT_CHANNEL struct holding nChannels elements.
- * \param toolsInfo Pointer to tools info struct of current element.
- * \param adjThrStateElement Pointer to ATS_ELEMENT holding enFacPatch states.
- * \param nChannels Number of channels in element.
- * \param usePatchTool Apply the weighting tool 0 (no) else (yes).
- *
- * \return void
- */
-static
-void FDKaacEnc_calcWeighting(PE_DATA *peData,
- PSY_OUT_CHANNEL* psyOutChannel[(2)],
- QC_OUT_CHANNEL* qcOutChannel[(2)],
- struct TOOLSINFO *toolsInfo,
- ATS_ELEMENT* adjThrStateElement,
- const INT nChannels,
- const INT usePatchTool)
-{
- int ch, noShortWindowInFrame = TRUE;
- INT exePatchM = 0;
-
- for (ch=0; ch<nChannels; ch++) {
- if (psyOutChannel[ch]->lastWindowSequence == SHORT_WINDOW) {
- noShortWindowInFrame = FALSE;
- }
- FDKmemclear(qcOutChannel[ch]->sfbEnFacLd, MAX_GROUPED_SFB*sizeof(FIXP_DBL));
- }
-
- if (usePatchTool==0) {
- return; /* tool is disabled */
- }
-
- for (ch=0; ch<nChannels; ch++) {
-
- PSY_OUT_CHANNEL *psyOutChan = psyOutChannel[ch];
-
- if (noShortWindowInFrame) { /* retain energy ratio between blocks of different length */
-
- FIXP_DBL nrgSum14, nrgSum12, nrgSum34, nrgTotal;
- FIXP_DBL nrgFacLd_14, nrgFacLd_12, nrgFacLd_34;
- INT usePatch, exePatch;
- int sfb, sfbGrp, nLinesSum = 0;
-
- nrgSum14 = nrgSum12 = nrgSum34 = nrgTotal = FL2FXCONST_DBL(0.f);
-
- /* calculate flatness of audible spectrum, i.e. spectrum above masking threshold. */
- for (sfbGrp = 0;sfbGrp < psyOutChannel[ch]->sfbCnt; sfbGrp+=psyOutChannel[ch]->sfbPerGroup) {
- for (sfb=0; sfb<psyOutChannel[ch]->maxSfbPerGroup; sfb++) {
- FIXP_DBL nrgFac12 = CalcInvLdData(psyOutChan->sfbEnergyLdData[sfbGrp+sfb]>>1); /* nrg^(1/2) */
- FIXP_DBL nrgFac14 = CalcInvLdData(psyOutChan->sfbEnergyLdData[sfbGrp+sfb]>>2); /* nrg^(1/4) */
-
- /* maximal number of bands is 64, results scaling factor 6 */
- nLinesSum += peData->peChannelData[ch].sfbNLines[sfbGrp+sfb]; /* relevant lines */
- nrgTotal += ( psyOutChan->sfbEnergy[sfbGrp+sfb] >> 6 ); /* sum up nrg */
- nrgSum12 += ( nrgFac12 >> 6 ); /* sum up nrg^(2/4) */
- nrgSum14 += ( nrgFac14 >> 6 ); /* sum up nrg^(1/4) */
- nrgSum34 += ( fMult(nrgFac14, nrgFac12) >> 6 ); /* sum up nrg^(3/4) */
- }
- }
-
- nrgTotal = CalcLdData(nrgTotal); /* get ld64 of total nrg */
-
- nrgFacLd_14 = CalcLdData(nrgSum14) - nrgTotal; /* ld64(nrgSum14/nrgTotal) */
- nrgFacLd_12 = CalcLdData(nrgSum12) - nrgTotal; /* ld64(nrgSum12/nrgTotal) */
- nrgFacLd_34 = CalcLdData(nrgSum34) - nrgTotal; /* ld64(nrgSum34/nrgTotal) */
-
- adjThrStateElement->chaosMeasureEnFac[ch] = FDKmax( FL2FXCONST_DBL(0.1875f), fDivNorm(nLinesSum,psyOutChan->sfbOffsets[psyOutChan->sfbCnt]) );
-
- usePatch = (adjThrStateElement->chaosMeasureEnFac[ch] > FL2FXCONST_DBL(0.78125f));
- exePatch = ((usePatch) && (adjThrStateElement->lastEnFacPatch[ch]));
-
- for (sfbGrp = 0;sfbGrp < psyOutChannel[ch]->sfbCnt; sfbGrp+=psyOutChannel[ch]->sfbPerGroup) {
- for (sfb=0; sfb<psyOutChannel[ch]->maxSfbPerGroup; sfb++) {
-
- INT sfbExePatch;
-
- /* for MS coupled SFBs, also execute patch in side channel if done in mid channel */
- if ((ch == 1) && (toolsInfo->msMask[sfbGrp+sfb])) {
- sfbExePatch = exePatchM;
- }
- else {
- sfbExePatch = exePatch;
- }
-
- if ( (sfbExePatch) && (psyOutChan->sfbEnergy[sfbGrp+sfb]>FL2FXCONST_DBL(0.f)) )
- {
- /* execute patch based on spectral flatness calculated above */
- if (adjThrStateElement->chaosMeasureEnFac[ch] > FL2FXCONST_DBL(0.8125f)) {
- qcOutChannel[ch]->sfbEnFacLd[sfbGrp+sfb] = ( (nrgFacLd_14 + (psyOutChan->sfbEnergyLdData[sfbGrp+sfb]+(psyOutChan->sfbEnergyLdData[sfbGrp+sfb]>>1)))>>1 ); /* sfbEnergy^(3/4) */
- }
- else if (adjThrStateElement->chaosMeasureEnFac[ch] > FL2FXCONST_DBL(0.796875f)) {
- qcOutChannel[ch]->sfbEnFacLd[sfbGrp+sfb] = ( (nrgFacLd_12 + psyOutChan->sfbEnergyLdData[sfbGrp+sfb])>>1 ); /* sfbEnergy^(2/4) */
- }
- else {
- qcOutChannel[ch]->sfbEnFacLd[sfbGrp+sfb] = ( (nrgFacLd_34 + (psyOutChan->sfbEnergyLdData[sfbGrp+sfb]>>1))>>1 ); /* sfbEnergy^(1/4) */
- }
- qcOutChannel[ch]->sfbEnFacLd[sfbGrp+sfb] = fixMin(qcOutChannel[ch]->sfbEnFacLd[sfbGrp+sfb],(FIXP_DBL)0);
-
- }
- }
- } /* sfb loop */
-
- adjThrStateElement->lastEnFacPatch[ch] = usePatch;
- exePatchM = exePatch;
- }
- else {
- /* !noShortWindowInFrame */
- adjThrStateElement->chaosMeasureEnFac[ch] = FL2FXCONST_DBL(0.75f);
- adjThrStateElement->lastEnFacPatch[ch] = TRUE; /* allow use of sfbEnFac patch in upcoming frame */
- }
-
- } /* ch loop */
-
-}
-
-
-
-
-/*****************************************************************************
-functionname: FDKaacEnc_calcPe
-description: calculate pe for both channels
-*****************************************************************************/
-static
-void FDKaacEnc_calcPe(PSY_OUT_CHANNEL* psyOutChannel[(2)],
- QC_OUT_CHANNEL* qcOutChannel[(2)],
- PE_DATA *peData,
- const INT nChannels)
-{
- INT ch;
-
- peData->pe = peData->offset;
- peData->constPart = 0;
- peData->nActiveLines = 0;
- for(ch=0; ch<nChannels; ch++) {
- PE_CHANNEL_DATA *peChanData = &peData->peChannelData[ch];
- FDKaacEnc_calcSfbPe(&peData->peChannelData[ch],
- qcOutChannel[ch]->sfbWeightedEnergyLdData,
- qcOutChannel[ch]->sfbThresholdLdData,
- psyOutChannel[ch]->sfbCnt,
- psyOutChannel[ch]->sfbPerGroup,
- psyOutChannel[ch]->maxSfbPerGroup,
- psyOutChannel[ch]->isBook,
- psyOutChannel[ch]->isScale);
-
- peData->pe += peChanData->pe;
- peData->constPart += peChanData->constPart;
- peData->nActiveLines += peChanData->nActiveLines;
- }
-}
-
-void FDKaacEnc_peCalculation(PE_DATA *peData,
- PSY_OUT_CHANNEL* psyOutChannel[(2)],
- QC_OUT_CHANNEL* qcOutChannel[(2)],
- struct TOOLSINFO *toolsInfo,
- ATS_ELEMENT* adjThrStateElement,
- const INT nChannels)
-{
- /* constants that will not change during successive pe calculations */
- FDKaacEnc_preparePe(peData, psyOutChannel, qcOutChannel, nChannels, adjThrStateElement->peOffset);
-
- /* calculate weighting factor for threshold adjustment */
- FDKaacEnc_calcWeighting(peData, psyOutChannel, qcOutChannel, toolsInfo, adjThrStateElement, nChannels, 1);
-{
- /* no weighting of threholds and energies for mlout */
- /* weight energies and thresholds */
- int ch;
- for (ch=0; ch<nChannels; ch++) {
-
- int sfb, sfbGrp;
- QC_OUT_CHANNEL* pQcOutCh = qcOutChannel[ch];
-
- for (sfbGrp = 0;sfbGrp < psyOutChannel[ch]->sfbCnt; sfbGrp+=psyOutChannel[ch]->sfbPerGroup) {
- for (sfb=0; sfb<psyOutChannel[ch]->maxSfbPerGroup; sfb++) {
- pQcOutCh->sfbWeightedEnergyLdData[sfb+sfbGrp] = pQcOutCh->sfbEnergyLdData[sfb+sfbGrp] - pQcOutCh->sfbEnFacLd[sfb+sfbGrp];
- pQcOutCh->sfbThresholdLdData[sfb+sfbGrp] -= pQcOutCh->sfbEnFacLd[sfb+sfbGrp];
- }
- }
- }
-}
-
- /* pe without reduction */
- FDKaacEnc_calcPe(psyOutChannel, qcOutChannel, peData, nChannels);
-}
-
-
-
-/*****************************************************************************
-functionname: FDKaacEnc_FDKaacEnc_calcPeNoAH
-description: sum the pe data only for bands where avoid hole is inactive
-*****************************************************************************/
-static void FDKaacEnc_FDKaacEnc_calcPeNoAH(INT *pe,
- INT *constPart,
- INT *nActiveLines,
- PE_DATA *peData,
- UCHAR ahFlag[(2)][MAX_GROUPED_SFB],
- PSY_OUT_CHANNEL* psyOutChannel[(2)],
- const INT nChannels)
-{
- INT ch, sfb,sfbGrp;
-
- INT pe_tmp = peData->offset;
- INT constPart_tmp = 0;
- INT nActiveLines_tmp = 0;
- for(ch=0; ch<nChannels; ch++) {
- PE_CHANNEL_DATA *peChanData = &peData->peChannelData[ch];
- for(sfbGrp = 0;sfbGrp < psyOutChannel[ch]->sfbCnt;sfbGrp+= psyOutChannel[ch]->sfbPerGroup){
- for (sfb=0; sfb<psyOutChannel[ch]->maxSfbPerGroup; sfb++) {
- if(ahFlag[ch][sfbGrp+sfb] < AH_ACTIVE) {
- pe_tmp += peChanData->sfbPe[sfbGrp+sfb];
- constPart_tmp += peChanData->sfbConstPart[sfbGrp+sfb];
- nActiveLines_tmp += peChanData->sfbNActiveLines[sfbGrp+sfb];
- }
- }
- }
- }
- /* correct scaled pe and constPart values */
- *pe = pe_tmp >> PE_CONSTPART_SHIFT;
- *constPart = constPart_tmp >> PE_CONSTPART_SHIFT;
-
- *nActiveLines = nActiveLines_tmp;
-}
-
-
-/*****************************************************************************
-functionname: FDKaacEnc_reduceThresholdsCBR
-description: apply reduction formula
-*****************************************************************************/
-static const FIXP_DBL limitThrReducedLdData = (FIXP_DBL)0x00008000; /*FL2FXCONST_DBL(FDKpow(2.0,-LD_DATA_SCALING/4.0));*/
-
-static void FDKaacEnc_reduceThresholdsCBR(QC_OUT_CHANNEL* qcOutChannel[(2)],
- PSY_OUT_CHANNEL* psyOutChannel[(2)],
- UCHAR ahFlag[(2)][MAX_GROUPED_SFB],
- FIXP_DBL thrExp[(2)][MAX_GROUPED_SFB],
- const INT nChannels,
- const FIXP_DBL redVal,
- const SCHAR redValScaling)
-{
- INT ch, sfb, sfbGrp;
- FIXP_DBL sfbEnLdData, sfbThrLdData, sfbThrReducedLdData;
- FIXP_DBL sfbThrExp;
-
- for(ch=0; ch<nChannels; ch++) {
- QC_OUT_CHANNEL *qcOutChan = qcOutChannel[ch];
- for(sfbGrp = 0; sfbGrp < psyOutChannel[ch]->sfbCnt; sfbGrp+= psyOutChannel[ch]->sfbPerGroup){
- for (sfb=0; sfb<psyOutChannel[ch]->maxSfbPerGroup; sfb++) {
- sfbEnLdData = qcOutChan->sfbWeightedEnergyLdData[sfbGrp+sfb];
- sfbThrLdData = qcOutChan->sfbThresholdLdData[sfbGrp+sfb];
- sfbThrExp = thrExp[ch][sfbGrp+sfb];
- if ((sfbEnLdData > sfbThrLdData) && (ahFlag[ch][sfbGrp+sfb] != AH_ACTIVE)) {
-
- /* threshold reduction formula:
- float tmp = thrExp[ch][sfb]+redVal;
- tmp *= tmp;
- sfbThrReduced = tmp*tmp;
- */
- int minScale = fixMin(CountLeadingBits(sfbThrExp), CountLeadingBits(redVal) - (DFRACT_BITS-1-redValScaling) )-1;
-
- /* 4*log( sfbThrExp + redVal ) */
- sfbThrReducedLdData = CalcLdData(fAbs(scaleValue(sfbThrExp, minScale) + scaleValue(redVal,(DFRACT_BITS-1-redValScaling)+minScale)))
- - (FIXP_DBL)(minScale<<(DFRACT_BITS-1-LD_DATA_SHIFT));
- sfbThrReducedLdData <<= 2;
-
- /* avoid holes */
- if ( ((sfbThrReducedLdData - sfbEnLdData) > qcOutChan->sfbMinSnrLdData[sfbGrp+sfb] )
- && (ahFlag[ch][sfbGrp+sfb] != NO_AH) )
- {
- if (qcOutChan->sfbMinSnrLdData[sfbGrp+sfb] > (FL2FXCONST_DBL(-1.0f) - sfbEnLdData) ){
- sfbThrReducedLdData = fixMax((qcOutChan->sfbMinSnrLdData[sfbGrp+sfb] + sfbEnLdData), sfbThrLdData);
- }
- else sfbThrReducedLdData = sfbThrLdData;
- ahFlag[ch][sfbGrp+sfb] = AH_ACTIVE;
- }
-
- /* minimum of 29 dB Ratio for Thresholds */
- if ((sfbEnLdData+(FIXP_DBL)MAXVAL_DBL) > FL2FXCONST_DBL(9.6336206/LD_DATA_SCALING)){
- sfbThrReducedLdData = fixMax(sfbThrReducedLdData, (sfbEnLdData - FL2FXCONST_DBL(9.6336206/LD_DATA_SCALING)));
- }
-
- qcOutChan->sfbThresholdLdData[sfbGrp+sfb] = sfbThrReducedLdData;
- }
- }
- }
- }
-}
-
-/* similar to prepareSfbPe1() */
-static FIXP_DBL FDKaacEnc_calcChaosMeasure(PSY_OUT_CHANNEL *psyOutChannel,
- const FIXP_DBL *sfbFormFactorLdData)
-{
- #define SCALE_FORM_FAC (4) /* (SCALE_FORM_FAC+FORM_FAC_SHIFT) >= ld(FRAME_LENGTH)*/
- #define SCALE_NRGS (8)
- #define SCALE_NLINES (16)
- #define SCALE_NRGS_SQRT4 (2) /* 0.25 * SCALE_NRGS */
- #define SCALE_NLINES_P34 (12) /* 0.75 * SCALE_NLINES */
-
- INT sfbGrp, sfb;
- FIXP_DBL chaosMeasure;
- INT frameNLines = 0;
- FIXP_DBL frameFormFactor = FL2FXCONST_DBL(0.f);
- FIXP_DBL frameEnergy = FL2FXCONST_DBL(0.f);
-
- for (sfbGrp=0; sfbGrp<psyOutChannel->sfbCnt; sfbGrp+=psyOutChannel->sfbPerGroup) {
- for (sfb=0; sfb<psyOutChannel->maxSfbPerGroup; sfb++){
- if (psyOutChannel->sfbEnergyLdData[sfbGrp+sfb] > psyOutChannel->sfbThresholdLdData[sfbGrp+sfb]) {
- frameFormFactor += (CalcInvLdData(sfbFormFactorLdData[sfbGrp+sfb])>>SCALE_FORM_FAC);
- frameNLines += (psyOutChannel->sfbOffsets[sfbGrp+sfb+1] - psyOutChannel->sfbOffsets[sfbGrp+sfb]);
- frameEnergy += (psyOutChannel->sfbEnergy[sfbGrp+sfb]>>SCALE_NRGS);
- }
- }
- }
-
- if(frameNLines > 0){
-
- /* frameNActiveLines = frameFormFactor*2^FORM_FAC_SHIFT * ((frameEnergy *2^SCALE_NRGS)/frameNLines)^-0.25
- chaosMeasure = frameNActiveLines / frameNLines */
- chaosMeasure =
- CalcInvLdData( (((CalcLdData(frameFormFactor)>>1) -
- (CalcLdData(frameEnergy)>>(2+1))) -
- (fMultDiv2(FL2FXCONST_DBL(0.75f),CalcLdData((FIXP_DBL)frameNLines<<(DFRACT_BITS-1-SCALE_NLINES))) -
- (((FIXP_DBL)(SCALE_FORM_FAC-SCALE_NRGS_SQRT4+FORM_FAC_SHIFT-(SCALE_NLINES_P34))<<(DFRACT_BITS-1-LD_DATA_SHIFT))>>1))
- )<<1 );
- } else {
-
- /* assuming total chaos, if no sfb is above thresholds */
- chaosMeasure = FL2FXCONST_DBL(1.f);
- }
-
- return chaosMeasure;
-}
-
-/* apply reduction formula for VBR-mode */
-static void FDKaacEnc_reduceThresholdsVBR(QC_OUT_CHANNEL* qcOutChannel[(2)],
- PSY_OUT_CHANNEL* psyOutChannel[(2)],
- UCHAR ahFlag[(2)][MAX_GROUPED_SFB],
- FIXP_DBL thrExp[(2)][MAX_GROUPED_SFB],
- const INT nChannels,
- const FIXP_DBL vbrQualFactor,
- FIXP_DBL* chaosMeasureOld)
-{
- INT ch, sfbGrp, sfb;
- FIXP_DBL chGroupEnergy[TRANS_FAC][2];/*energy for each group and channel*/
- FIXP_DBL chChaosMeasure[2];
- FIXP_DBL frameEnergy = FL2FXCONST_DBL(1e-10f);
- FIXP_DBL chaosMeasure = FL2FXCONST_DBL(0.f);
- FIXP_DBL sfbEnLdData, sfbThrLdData, sfbThrExp;
- FIXP_DBL sfbThrReducedLdData;
- FIXP_DBL chaosMeasureAvg;
- INT groupCnt; /* loop counter */
- FIXP_DBL redVal[TRANS_FAC]; /* reduction values; in short-block case one redVal for each group */
- QC_OUT_CHANNEL *qcOutChan = NULL;
- PSY_OUT_CHANNEL *psyOutChan = NULL;
-
-#define SCALE_GROUP_ENERGY (8)
-
-#define CONST_CHAOS_MEAS_AVG_FAC_0 (FL2FXCONST_DBL(0.25f))
-#define CONST_CHAOS_MEAS_AVG_FAC_1 (FL2FXCONST_DBL(1.f-0.25f))
-
-#define MIN_LDTHRESH (FL2FXCONST_DBL(-0.515625f))
-
-
- for(ch=0; ch<nChannels; ch++){
- qcOutChan = qcOutChannel[ch];
- psyOutChan = psyOutChannel[ch];
-
- /* adding up energy for each channel and each group separately */
- FIXP_DBL chEnergy = FL2FXCONST_DBL(0.f);
- groupCnt=0;
-
- for (sfbGrp=0; sfbGrp<psyOutChan->sfbCnt; sfbGrp+=psyOutChan->sfbPerGroup, groupCnt++) {
- chGroupEnergy[groupCnt][ch] = FL2FXCONST_DBL(0.f);
- for (sfb=0; sfb<psyOutChan->maxSfbPerGroup; sfb++){
- chGroupEnergy[groupCnt][ch] += (psyOutChan->sfbEnergy[sfbGrp+sfb]>>SCALE_GROUP_ENERGY);
- }
- chEnergy += chGroupEnergy[groupCnt][ch];
- }
- frameEnergy += chEnergy;
-
- /* chaosMeasure */
- if (psyOutChannel[0]->lastWindowSequence == SHORT_WINDOW) {
- chChaosMeasure[ch] = FL2FXCONST_DBL(0.5f); /* assume a constant chaos measure of 0.5f for short blocks */
- } else {
- chChaosMeasure[ch] = FDKaacEnc_calcChaosMeasure(psyOutChannel[ch], qcOutChannel[ch]->sfbFormFactorLdData);
- }
- chaosMeasure += fMult(chChaosMeasure[ch], chEnergy);
- }
-
- if(frameEnergy > chaosMeasure) {
- INT scale = CntLeadingZeros(frameEnergy) - 1;
- FIXP_DBL num = chaosMeasure<<scale;
- FIXP_DBL denum = frameEnergy<<scale;
- chaosMeasure = schur_div(num,denum,16);
- }
- else {
- chaosMeasure = FL2FXCONST_DBL(1.f);
- }
-
- chaosMeasureAvg = fMult(CONST_CHAOS_MEAS_AVG_FAC_0, chaosMeasure) +
- fMult(CONST_CHAOS_MEAS_AVG_FAC_1, *chaosMeasureOld); /* averaging chaos measure */
- *chaosMeasureOld = chaosMeasure = (fixMin(chaosMeasure, chaosMeasureAvg)); /* use min-value, safe for next frame */
-
- /* characteristic curve
- chaosMeasure = 0.2f + 0.7f/0.3f * (chaosMeasure - 0.2f);
- chaosMeasure = fixMin(1.0f, fixMax(0.1f, chaosMeasure));
- constants scaled by 4.f
- */
- chaosMeasure = ((FL2FXCONST_DBL(0.2f)>>2) + fMult(FL2FXCONST_DBL(0.7f/(4.f*0.3f)), (chaosMeasure - FL2FXCONST_DBL(0.2f))));
- chaosMeasure = (fixMin((FIXP_DBL)(FL2FXCONST_DBL(1.0f)>>2), fixMax((FIXP_DBL)(FL2FXCONST_DBL(0.1f)>>2), chaosMeasure)))<<2;
-
- /* calculation of reduction value */
- if (psyOutChannel[0]->lastWindowSequence == SHORT_WINDOW){ /* short-blocks */
- FDK_ASSERT(TRANS_FAC==8);
- #define WIN_TYPE_SCALE (3)
-
- INT sfbGrp, groupCnt=0;
- for (sfbGrp=0; sfbGrp<psyOutChan->sfbCnt; sfbGrp+=psyOutChan->sfbPerGroup,groupCnt++) {
-
- FIXP_DBL groupEnergy = FL2FXCONST_DBL(0.f);
-
- for(ch=0;ch<nChannels;ch++){
- groupEnergy += chGroupEnergy[groupCnt][ch]; /* adding up the channels groupEnergy */
- }
-
- FDK_ASSERT(psyOutChannel[0]->groupLen[groupCnt]<=INV_INT_TAB_SIZE);
- groupEnergy = fMult(groupEnergy,invInt[psyOutChannel[0]->groupLen[groupCnt]]); /* correction of group energy */
- groupEnergy = fixMin(groupEnergy, frameEnergy>>WIN_TYPE_SCALE); /* do not allow an higher redVal as calculated framewise */
-
- groupEnergy>>=2; /* 2*WIN_TYPE_SCALE = 6 => 6+2 = 8 ==> 8/4 = int number */
-
- redVal[groupCnt] = fMult(fMult(vbrQualFactor,chaosMeasure),
- CalcInvLdData(CalcLdData(groupEnergy)>>2) )
- << (int)( ( 2 + (2*WIN_TYPE_SCALE) + SCALE_GROUP_ENERGY )>>2 ) ;
-
- }
- } else { /* long-block */
-
- redVal[0] = fMult( fMult(vbrQualFactor,chaosMeasure),
- CalcInvLdData(CalcLdData(frameEnergy)>>2) )
- << (int)( SCALE_GROUP_ENERGY>>2 ) ;
- }
-
- for(ch=0; ch<nChannels; ch++) {
- qcOutChan = qcOutChannel[ch];
- psyOutChan = psyOutChannel[ch];
-
- for (sfbGrp=0; sfbGrp<psyOutChan->sfbCnt; sfbGrp+=psyOutChan->sfbPerGroup) {
- for (sfb=0; sfb<psyOutChan->maxSfbPerGroup; sfb++){
-
- sfbEnLdData = (qcOutChan->sfbWeightedEnergyLdData[sfbGrp+sfb]);
- sfbThrLdData = (qcOutChan->sfbThresholdLdData[sfbGrp+sfb]);
- sfbThrExp = thrExp[ch][sfbGrp+sfb];
-
- if ( (sfbThrLdData>=MIN_LDTHRESH) && (sfbEnLdData > sfbThrLdData) && (ahFlag[ch][sfbGrp+sfb] != AH_ACTIVE)) {
-
- /* Short-Window */
- if (psyOutChannel[ch]->lastWindowSequence == SHORT_WINDOW) {
- const int groupNumber = (int) sfb/psyOutChan->sfbPerGroup;
-
- FDK_ASSERT(INV_SQRT4_TAB_SIZE>psyOutChan->groupLen[groupNumber]);
-
- sfbThrExp = fMult(sfbThrExp, fMult( FL2FXCONST_DBL(2.82f/4.f), invSqrt4[psyOutChan->groupLen[groupNumber]]))<<2 ;
-
- if ( sfbThrExp <= (limitThrReducedLdData-redVal[groupNumber]) ) {
- sfbThrReducedLdData = FL2FXCONST_DBL(-1.0f);
- }
- else {
- if ((FIXP_DBL)redVal[groupNumber] >= FL2FXCONST_DBL(1.0f)-sfbThrExp)
- sfbThrReducedLdData = FL2FXCONST_DBL(0.0f);
- else {
- /* threshold reduction formula */
- sfbThrReducedLdData = CalcLdData(sfbThrExp + redVal[groupNumber]);
- sfbThrReducedLdData <<= 2;
- }
- }
- sfbThrReducedLdData += ( CalcLdInt(psyOutChan->groupLen[groupNumber]) -
- ((FIXP_DBL)6<<(DFRACT_BITS-1-LD_DATA_SHIFT)) );
- }
-
- /* Long-Window */
- else {
- if ((FIXP_DBL)redVal[0] >= FL2FXCONST_DBL(1.0f)-sfbThrExp) {
- sfbThrReducedLdData = FL2FXCONST_DBL(0.0f);
- }
- else {
- /* threshold reduction formula */
- sfbThrReducedLdData = CalcLdData(sfbThrExp + redVal[0]);
- sfbThrReducedLdData <<= 2;
- }
- }
-
- /* avoid holes */
- if ( ((sfbThrReducedLdData - sfbEnLdData) > qcOutChan->sfbMinSnrLdData[sfbGrp+sfb] )
- && (ahFlag[ch][sfbGrp+sfb] != NO_AH) )
- {
- if (qcOutChan->sfbMinSnrLdData[sfbGrp+sfb] > (FL2FXCONST_DBL(-1.0f) - sfbEnLdData) ){
- sfbThrReducedLdData = fixMax((qcOutChan->sfbMinSnrLdData[sfbGrp+sfb] + sfbEnLdData), sfbThrLdData);
- }
- else sfbThrReducedLdData = sfbThrLdData;
- ahFlag[ch][sfbGrp+sfb] = AH_ACTIVE;
- }
-
- if (sfbThrReducedLdData<FL2FXCONST_DBL(-0.5f))
- sfbThrReducedLdData = FL2FXCONST_DBL(-1.f);
-
- /* minimum of 29 dB Ratio for Thresholds */
- if ((sfbEnLdData+FL2FXCONST_DBL(1.0f)) > FL2FXCONST_DBL(9.6336206/LD_DATA_SCALING)){
- sfbThrReducedLdData = fixMax(sfbThrReducedLdData, sfbEnLdData - FL2FXCONST_DBL(9.6336206/LD_DATA_SCALING));
- }
-
- sfbThrReducedLdData = fixMax(MIN_LDTHRESH,sfbThrReducedLdData);
-
- qcOutChan->sfbThresholdLdData[sfbGrp+sfb] = sfbThrReducedLdData;
- }
- }
- }
- }
-}
-
-/*****************************************************************************
-functionname: FDKaacEnc_correctThresh
-description: if pe difference deltaPe between desired pe and real pe is small enough,
-the difference can be distributed among the scale factor bands.
-New thresholds can be derived from this pe-difference
-*****************************************************************************/
-static void FDKaacEnc_correctThresh(CHANNEL_MAPPING* cm,
- QC_OUT_ELEMENT* qcElement[(8)],
- PSY_OUT_ELEMENT* psyOutElement[(8)],
- UCHAR ahFlag[(8)][(2)][MAX_GROUPED_SFB],
- FIXP_DBL thrExp[(8)][(2)][MAX_GROUPED_SFB],
- const FIXP_DBL redVal[(8)],
- const SCHAR redValScaling[(8)],
- const INT deltaPe,
- const INT processElements,
- const INT elementOffset)
-{
- INT ch, sfb, sfbGrp;
- QC_OUT_CHANNEL *qcOutChan;
- PSY_OUT_CHANNEL *psyOutChan;
- PE_CHANNEL_DATA *peChanData;
- FIXP_DBL thrFactorLdData;
- FIXP_DBL sfbEnLdData, sfbThrLdData, sfbThrReducedLdData;
- FIXP_DBL *sfbPeFactorsLdData[(8)][(2)];
- FIXP_DBL sfbNActiveLinesLdData[(8)][(2)][MAX_GROUPED_SFB];
- INT normFactorInt;
- FIXP_DBL normFactorLdData;
-
- INT nElements = elementOffset+processElements;
- INT elementId;
-
- /* scratch is empty; use temporal memory from quantSpec in QC_OUT_CHANNEL */
- for(elementId=elementOffset;elementId<nElements;elementId++) {
- for(ch=0; ch<cm->elInfo[elementId].nChannelsInEl; ch++) {
- SHORT* ptr = qcElement[elementId]->qcOutChannel[ch]->quantSpec;
- sfbPeFactorsLdData[elementId][ch] = (FIXP_DBL*)ptr;
- }
- }
-
- /* for each sfb calc relative factors for pe changes */
- normFactorInt = 0;
-
- for(elementId=elementOffset;elementId<nElements;elementId++) {
- if (cm->elInfo[elementId].elType != ID_DSE) {
-
- for(ch=0; ch<cm->elInfo[elementId].nChannelsInEl; ch++) {
-
- qcOutChan = qcElement[elementId]->qcOutChannel[ch];
- psyOutChan = psyOutElement[elementId]->psyOutChannel[ch];
- peChanData = &qcElement[elementId]->peData.peChannelData[ch];
-
- for(sfbGrp = 0; sfbGrp < psyOutChan->sfbCnt; sfbGrp+= psyOutChan->sfbPerGroup){
- for (sfb=0; sfb<psyOutChan->maxSfbPerGroup; sfb++) {
-
- if ( peChanData->sfbNActiveLines[sfbGrp+sfb] == 0 ) {
- sfbNActiveLinesLdData[elementId][ch][sfbGrp+sfb] = FL2FXCONST_DBL(-1.0f);
- }
- else {
- /* Both CalcLdInt and CalcLdData can be used!
- * No offset has to be subtracted, because sfbNActiveLinesLdData
- * is shorted while thrFactor calculation */
- sfbNActiveLinesLdData[elementId][ch][sfbGrp+sfb] = CalcLdInt(peChanData->sfbNActiveLines[sfbGrp+sfb]);
- }
- if ( ((ahFlag[elementId][ch][sfbGrp+sfb] < AH_ACTIVE) || (deltaPe > 0)) &&
- peChanData->sfbNActiveLines[sfbGrp+sfb] != 0 )
- {
- if (thrExp[elementId][ch][sfbGrp+sfb] > -redVal[elementId]) {
-
- /* sfbPeFactors[ch][sfbGrp+sfb] = peChanData->sfbNActiveLines[sfbGrp+sfb] /
- (thrExp[elementId][ch][sfbGrp+sfb] + redVal[elementId]); */
-
- int minScale = fixMin(CountLeadingBits(thrExp[elementId][ch][sfbGrp+sfb]), CountLeadingBits(redVal[elementId]) - (DFRACT_BITS-1-redValScaling[elementId]) ) - 1;
-
- /* sumld = ld64( sfbThrExp + redVal ) */
- FIXP_DBL sumLd = CalcLdData(scaleValue(thrExp[elementId][ch][sfbGrp+sfb], minScale) + scaleValue(redVal[elementId], (DFRACT_BITS-1-redValScaling[elementId])+minScale))
- - (FIXP_DBL)(minScale<<(DFRACT_BITS-1-LD_DATA_SHIFT));
-
- if (sumLd < FL2FXCONST_DBL(0.f)) {
- sfbPeFactorsLdData[elementId][ch][sfbGrp+sfb] = sfbNActiveLinesLdData[elementId][ch][sfbGrp+sfb] - sumLd;
- }
- else {
- if ( sfbNActiveLinesLdData[elementId][ch][sfbGrp+sfb] > (FL2FXCONST_DBL(-1.f) + sumLd) ) {
- sfbPeFactorsLdData[elementId][ch][sfbGrp+sfb] = sfbNActiveLinesLdData[elementId][ch][sfbGrp+sfb] - sumLd;
- }
- else {
- sfbPeFactorsLdData[elementId][ch][sfbGrp+sfb] = sfbNActiveLinesLdData[elementId][ch][sfbGrp+sfb];
- }
- }
-
- normFactorInt += (INT)CalcInvLdData(sfbPeFactorsLdData[elementId][ch][sfbGrp+sfb]);
- }
- else sfbPeFactorsLdData[elementId][ch][sfbGrp+sfb] = FL2FXCONST_DBL(1.0f);
- }
- else sfbPeFactorsLdData[elementId][ch][sfbGrp+sfb] = FL2FXCONST_DBL(-1.0f);
- }
- }
- }
- }
- }
-
- /* normFactorLdData = ld64(deltaPe/normFactorInt) */
- normFactorLdData = CalcLdData((FIXP_DBL)((deltaPe<0) ? (-deltaPe) : (deltaPe))) - CalcLdData((FIXP_DBL)normFactorInt);
-
- /* distribute the pe difference to the scalefactors
- and calculate the according thresholds */
- for(elementId=elementOffset;elementId<nElements;elementId++) {
- if (cm->elInfo[elementId].elType != ID_DSE) {
-
- for(ch=0; ch<cm->elInfo[elementId].nChannelsInEl; ch++) {
- qcOutChan = qcElement[elementId]->qcOutChannel[ch];
- psyOutChan = psyOutElement[elementId]->psyOutChannel[ch];
- peChanData = &qcElement[elementId]->peData.peChannelData[ch];
-
- for(sfbGrp = 0;sfbGrp < psyOutChan->sfbCnt;sfbGrp+= psyOutChan->sfbPerGroup){
- for (sfb=0; sfb<psyOutChan->maxSfbPerGroup; sfb++) {
-
- if (peChanData->sfbNActiveLines[sfbGrp+sfb] > 0) {
-
- /* pe difference for this sfb */
- if ( (sfbPeFactorsLdData[elementId][ch][sfbGrp+sfb]==FL2FXCONST_DBL(-1.0f)) ||
- (deltaPe==0) )
- {
- thrFactorLdData = FL2FXCONST_DBL(0.f);
- }
- else {
- /* new threshold */
- FIXP_DBL tmp = CalcInvLdData(sfbPeFactorsLdData[elementId][ch][sfbGrp+sfb] + normFactorLdData - sfbNActiveLinesLdData[elementId][ch][sfbGrp+sfb] - FL2FXCONST_DBL((float)LD_DATA_SHIFT/LD_DATA_SCALING));
-
- /* limit thrFactor to 60dB */
- tmp = (deltaPe<0) ? tmp : (-tmp);
- thrFactorLdData = FDKmin(tmp, FL2FXCONST_DBL(20.f/LD_DATA_SCALING));
- }
-
- /* new threshold */
- sfbThrLdData = qcOutChan->sfbThresholdLdData[sfbGrp+sfb];
- sfbEnLdData = qcOutChan->sfbWeightedEnergyLdData[sfbGrp+sfb];
-
- if (thrFactorLdData < FL2FXCONST_DBL(0.f)) {
- if( sfbThrLdData > (FL2FXCONST_DBL(-1.f)-thrFactorLdData) ) {
- sfbThrReducedLdData = sfbThrLdData + thrFactorLdData;
- }
- else {
- sfbThrReducedLdData = FL2FXCONST_DBL(-1.f);
- }
- }
- else{
- sfbThrReducedLdData = sfbThrLdData + thrFactorLdData;
- }
-
- /* avoid hole */
- if ( (sfbThrReducedLdData - sfbEnLdData > qcOutChan->sfbMinSnrLdData[sfbGrp+sfb]) &&
- (ahFlag[elementId][ch][sfbGrp+sfb] == AH_INACTIVE) )
- {
- /* sfbThrReduced = max(psyOutChan[ch]->sfbMinSnr[i] * sfbEn, sfbThr); */
- if ( sfbEnLdData > (sfbThrLdData-qcOutChan->sfbMinSnrLdData[sfbGrp+sfb]) ) {
- sfbThrReducedLdData = qcOutChan->sfbMinSnrLdData[sfbGrp+sfb] + sfbEnLdData;
- }
- else {
- sfbThrReducedLdData = sfbThrLdData;
- }
- ahFlag[elementId][ch][sfbGrp+sfb] = AH_ACTIVE;
- }
-
- qcOutChan->sfbThresholdLdData[sfbGrp+sfb] = sfbThrReducedLdData;
- }
- }
- }
- }
- }
- }
-}
-
-/*****************************************************************************
- functionname: FDKaacEnc_reduceMinSnr
- description: if the desired pe can not be reached, reduce pe by
- reducing minSnr
-*****************************************************************************/
-void FDKaacEnc_reduceMinSnr(CHANNEL_MAPPING* cm,
- QC_OUT_ELEMENT* qcElement[(8)],
- PSY_OUT_ELEMENT* psyOutElement[(8)],
- UCHAR ahFlag[(8)][(2)][MAX_GROUPED_SFB],
- const INT desiredPe,
- INT* redPeGlobal,
- const INT processElements,
- const INT elementOffset)
-
-{
- INT elementId;
- INT nElements = elementOffset+processElements;
-
- INT newGlobalPe = *redPeGlobal;
-
- for(elementId=elementOffset;elementId<nElements;elementId++) {
- if (cm->elInfo[elementId].elType != ID_DSE) {
- INT ch;
- INT maxSfbPerGroup[2];
- INT sfbCnt[2];
- INT sfbPerGroup[2];
-
- for(ch=0; ch<cm->elInfo[elementId].nChannelsInEl; ch++) {
- maxSfbPerGroup[ch] = psyOutElement[elementId]->psyOutChannel[ch]->maxSfbPerGroup-1;
- sfbCnt[ch] = psyOutElement[elementId]->psyOutChannel[ch]->sfbCnt;
- sfbPerGroup[ch] = psyOutElement[elementId]->psyOutChannel[ch]->sfbPerGroup;
- }
-
- PE_DATA *peData = &qcElement[elementId]->peData;
-
- do
- {
- for(ch=0; ch<cm->elInfo[elementId].nChannelsInEl; ch++) {
-
- INT sfb, sfbGrp;
- QC_OUT_CHANNEL *qcOutChan = qcElement[elementId]->qcOutChannel[ch];
- INT noReduction = 1;
-
- if (maxSfbPerGroup[ch]>=0) { /* sfb in next channel */
- INT deltaPe = 0;
- sfb = maxSfbPerGroup[ch]--;
- noReduction = 0;
-
- for (sfbGrp = 0; sfbGrp < sfbCnt[ch]; sfbGrp += sfbPerGroup[ch]) {
-
- if (ahFlag[elementId][ch][sfbGrp+sfb] != NO_AH &&
- qcOutChan->sfbMinSnrLdData[sfbGrp+sfb] < SnrLdFac)
- {
- /* increase threshold to new minSnr of 1dB */
- qcOutChan->sfbMinSnrLdData[sfbGrp+sfb] = SnrLdFac;
-
- /* sfbThrReduced = max(psyOutChan[ch]->sfbMinSnr[i] * sfbEn, sfbThr); */
- if ( qcOutChan->sfbWeightedEnergyLdData[sfbGrp+sfb] >= qcOutChan->sfbThresholdLdData[sfbGrp+sfb] - qcOutChan->sfbMinSnrLdData[sfbGrp+sfb] ) {
-
- qcOutChan->sfbThresholdLdData[sfbGrp+sfb] = qcOutChan->sfbWeightedEnergyLdData[sfbGrp+sfb] + qcOutChan->sfbMinSnrLdData[sfbGrp+sfb];
-
- /* calc new pe */
- /* C2 + C3*ld(1/0.8) = 1.5 */
- deltaPe -= (peData->peChannelData[ch].sfbPe[sfbGrp+sfb]>>PE_CONSTPART_SHIFT);
-
- /* sfbPe = 1.5 * sfbNLines */
- peData->peChannelData[ch].sfbPe[sfbGrp+sfb] = (3*peData->peChannelData[ch].sfbNLines[sfbGrp+sfb]) << (PE_CONSTPART_SHIFT-1);
- deltaPe += (peData->peChannelData[ch].sfbPe[sfbGrp+sfb]>>PE_CONSTPART_SHIFT);
- }
- }
-
- } /* sfbGrp loop */
-
- peData->pe += deltaPe;
- peData->peChannelData[ch].pe += deltaPe;
- newGlobalPe += deltaPe;
-
- /* stop if enough has been saved */
- if (peData->pe <= desiredPe) {
- goto bail;
- }
-
- } /* sfb > 0 */
-
- if ( (ch==(cm->elInfo[elementId].nChannelsInEl-1)) && noReduction ) {
- goto bail;
- }
-
- } /* ch loop */
-
- } while ( peData->pe > desiredPe);
-
- } /* != ID_DSE */
- } /* element loop */
-
-
-bail:
- /* update global PE */
- *redPeGlobal = newGlobalPe;
-}
-
-
-/*****************************************************************************
- functionname: FDKaacEnc_allowMoreHoles
- description: if the desired pe can not be reached, some more scalefactor
- bands have to be quantized to zero
-*****************************************************************************/
-static void FDKaacEnc_allowMoreHoles(CHANNEL_MAPPING* cm,
- QC_OUT_ELEMENT* qcElement[(8)],
- PSY_OUT_ELEMENT* psyOutElement[(8)],
- ATS_ELEMENT* AdjThrStateElement[(8)],
- UCHAR ahFlag[(8)][(2)][MAX_GROUPED_SFB],
- const INT desiredPe,
- const INT currentPe,
- const int processElements,
- const int elementOffset)
-{
- INT elementId;
- INT nElements = elementOffset+processElements;
- INT actPe = currentPe;
-
- if (actPe <= desiredPe) {
- return; /* nothing to do */
- }
-
- for (elementId = elementOffset;elementId<nElements;elementId++) {
- if (cm->elInfo[elementId].elType != ID_DSE) {
-
- INT ch, sfb, sfbGrp;
-
- PE_DATA *peData = &qcElement[elementId]->peData;
- const INT nChannels = cm->elInfo[elementId].nChannelsInEl;
-
- QC_OUT_CHANNEL* qcOutChannel[(2)] = {NULL};
- PSY_OUT_CHANNEL* psyOutChannel[(2)] = {NULL};
-
- for (ch=0; ch<nChannels; ch++) {
-
- /* init pointers */
- qcOutChannel[ch] = qcElement[elementId]->qcOutChannel[ch];
- psyOutChannel[ch] = psyOutElement[elementId]->psyOutChannel[ch];
-
- for(sfbGrp=0; sfbGrp < psyOutChannel[ch]->sfbCnt; sfbGrp+= psyOutChannel[ch]->sfbPerGroup) {
- for (sfb=psyOutChannel[ch]->maxSfbPerGroup; sfb<psyOutChannel[ch]->sfbPerGroup; sfb++) {
- peData->peChannelData[ch].sfbPe[sfbGrp+sfb] = 0;
- }
- }
- }
-
- /* for MS allow hole in the channel with less energy */
- if ( nChannels==2 && psyOutChannel[0]->lastWindowSequence==psyOutChannel[1]->lastWindowSequence ) {
-
- for (sfb=0; sfb<psyOutChannel[0]->maxSfbPerGroup; sfb++) {
- for(sfbGrp=0; sfbGrp < psyOutChannel[0]->sfbCnt; sfbGrp+=psyOutChannel[0]->sfbPerGroup) {
- if (psyOutElement[elementId]->toolsInfo.msMask[sfbGrp+sfb]) {
- FIXP_DBL EnergyLd_L = qcOutChannel[0]->sfbWeightedEnergyLdData[sfbGrp+sfb];
- FIXP_DBL EnergyLd_R = qcOutChannel[1]->sfbWeightedEnergyLdData[sfbGrp+sfb];
-
- /* allow hole in side channel ? */
- if ( (ahFlag[elementId][1][sfbGrp+sfb] != NO_AH) &&
- (((FL2FXCONST_DBL(-0.02065512648f)>>1) + (qcOutChannel[0]->sfbMinSnrLdData[sfbGrp+sfb]>>1))
- > ((EnergyLd_R>>1) - (EnergyLd_L>>1))) )
- {
- ahFlag[elementId][1][sfbGrp+sfb] = NO_AH;
- qcOutChannel[1]->sfbThresholdLdData[sfbGrp+sfb] = FL2FXCONST_DBL(0.015625f) + EnergyLd_R;
- actPe -= peData->peChannelData[1].sfbPe[sfbGrp+sfb]>>PE_CONSTPART_SHIFT;
- }
- /* allow hole in mid channel ? */
- else if ( (ahFlag[elementId][0][sfbGrp+sfb] != NO_AH) &&
- (((FL2FXCONST_DBL(-0.02065512648f)>>1) + (qcOutChannel[1]->sfbMinSnrLdData[sfbGrp+sfb]>>1))
- > ((EnergyLd_L>>1) - (EnergyLd_R>>1))) )
- {
- ahFlag[elementId][0][sfbGrp+sfb] = NO_AH;
- qcOutChannel[0]->sfbThresholdLdData[sfbGrp+sfb] = FL2FXCONST_DBL(0.015625f) + EnergyLd_L;
- actPe -= peData->peChannelData[0].sfbPe[sfbGrp+sfb]>>PE_CONSTPART_SHIFT;
- } /* if (ahFlag) */
- } /* if MS */
- } /* sfbGrp */
- if (actPe <= desiredPe) {
- return; /* stop if enough has been saved */
- }
- } /* sfb */
- } /* MS possible ? */
-
- /* more holes necessary? subsequently erase bands
- starting with low energies */
- INT startSfb[2];
- FIXP_DBL avgEnLD64,minEnLD64;
- INT ahCnt;
- FIXP_DBL ahCntLD64;
- INT enIdx;
- FIXP_DBL enLD64[4];
- FIXP_DBL avgEn;
-
- /* do not go below startSfb */
- for (ch=0; ch<nChannels; ch++) {
- if (psyOutChannel[ch]->lastWindowSequence != SHORT_WINDOW)
- startSfb[ch] = AdjThrStateElement[elementId]->ahParam.startSfbL;
- else
- startSfb[ch] = AdjThrStateElement[elementId]->ahParam.startSfbS;
- }
-
- /* calc avg and min energies of bands that avoid holes */
- avgEn = FL2FXCONST_DBL(0.0f);
- minEnLD64 = FL2FXCONST_DBL(0.0f);
- ahCnt = 0;
-
- for (ch=0; ch<nChannels; ch++) {
-
- sfbGrp=0;
- sfb=startSfb[ch];
-
- do {
- for (; sfb<psyOutChannel[ch]->maxSfbPerGroup; sfb++) {
- if ((ahFlag[elementId][ch][sfbGrp+sfb]!=NO_AH) &&
- (qcOutChannel[ch]->sfbWeightedEnergyLdData[sfbGrp+sfb] > qcOutChannel[ch]->sfbThresholdLdData[sfbGrp+sfb])){
- minEnLD64 = fixMin(minEnLD64,qcOutChannel[ch]->sfbEnergyLdData[sfbGrp+sfb]);
- avgEn += qcOutChannel[ch]->sfbEnergy[sfbGrp+sfb] >> 6;
- ahCnt++;
- }
- }
-
- sfbGrp += psyOutChannel[ch]->sfbPerGroup;
- sfb=0;
-
- } while (sfbGrp < psyOutChannel[ch]->sfbCnt);
- }
-
- if ( (avgEn == FL2FXCONST_DBL(0.0f)) || (ahCnt == 0) ) {
- avgEnLD64 = FL2FXCONST_DBL(0.0f);
- }
- else {
- avgEnLD64 = CalcLdData(avgEn);
- ahCntLD64 = CalcLdInt(ahCnt);
- avgEnLD64 = avgEnLD64 + FL2FXCONST_DBL(0.09375f) - ahCntLD64; /* compensate shift with 6 */
- }
-
- /* calc some energy borders between minEn and avgEn */
- /* for (enIdx=0; enIdx<4; enIdx++) */
- /* en[enIdx] = minEn * (float)FDKpow(avgEn/(minEn+FLT_MIN), (2*enIdx+1)/7.0f); */
- enLD64[0] = minEnLD64 + fMult((avgEnLD64-minEnLD64),FL2FXCONST_DBL(0.14285714285f));
- enLD64[1] = minEnLD64 + fMult((avgEnLD64-minEnLD64),FL2FXCONST_DBL(0.42857142857f));
- enLD64[2] = minEnLD64 + fMult((avgEnLD64-minEnLD64),FL2FXCONST_DBL(0.71428571428f));
- enLD64[3] = minEnLD64 + (avgEnLD64-minEnLD64);
-
- for (enIdx=0; enIdx<4; enIdx++) {
- INT noReduction = 1;
-
- INT maxSfbPerGroup[2];
- INT sfbCnt[2];
- INT sfbPerGroup[2];
-
- for(ch=0; ch<cm->elInfo[elementId].nChannelsInEl; ch++) {
- maxSfbPerGroup[ch] = psyOutElement[elementId]->psyOutChannel[ch]->maxSfbPerGroup-1;
- sfbCnt[ch] = psyOutElement[elementId]->psyOutChannel[ch]->sfbCnt;
- sfbPerGroup[ch] = psyOutElement[elementId]->psyOutChannel[ch]->sfbPerGroup;
- }
-
- do {
-
- noReduction = 1;
-
- for(ch=0; ch<cm->elInfo[elementId].nChannelsInEl; ch++) {
-
- INT sfb, sfbGrp;
-
- /* start with lowest energy border at highest sfb */
- if (maxSfbPerGroup[ch]>=startSfb[ch]) { /* sfb in next channel */
- sfb = maxSfbPerGroup[ch]--;
- noReduction = 0;
-
- for (sfbGrp = 0; sfbGrp < sfbCnt[ch]; sfbGrp += sfbPerGroup[ch]) {
- /* sfb energy below border ? */
- if (ahFlag[elementId][ch][sfbGrp+sfb] != NO_AH && qcOutChannel[ch]->sfbEnergyLdData[sfbGrp+sfb] < enLD64[enIdx]) {
- /* allow hole */
- ahFlag[elementId][ch][sfbGrp+sfb] = NO_AH;
- qcOutChannel[ch]->sfbThresholdLdData[sfbGrp+sfb] = FL2FXCONST_DBL(0.015625f) + qcOutChannel[ch]->sfbWeightedEnergyLdData[sfbGrp+sfb];
- actPe -= peData->peChannelData[ch].sfbPe[sfbGrp+sfb]>>PE_CONSTPART_SHIFT;
- }
- } /* sfbGrp */
-
- if (actPe <= desiredPe) {
- return; /* stop if enough has been saved */
- }
- } /* sfb > 0 */
- } /* ch loop */
-
- } while( (noReduction == 0) && (actPe > desiredPe) );
-
- if (actPe <= desiredPe) {
- return; /* stop if enough has been saved */
- }
-
- } /* enIdx loop */
-
- } /* EOF DSE-suppression */
- } /* EOF for all elements... */
-
-}
-
-/* reset avoid hole flags from AH_ACTIVE to AH_INACTIVE */
-static void FDKaacEnc_resetAHFlags( UCHAR ahFlag[(2)][MAX_GROUPED_SFB],
- const int nChannels,
- PSY_OUT_CHANNEL *psyOutChannel[(2)])
-{
- int ch, sfb, sfbGrp;
-
- for(ch=0; ch<nChannels; ch++) {
- for (sfbGrp=0; sfbGrp < psyOutChannel[ch]->sfbCnt; sfbGrp+=psyOutChannel[ch]->sfbPerGroup) {
- for (sfb=0; sfb<psyOutChannel[ch]->maxSfbPerGroup; sfb++) {
- if ( ahFlag[ch][sfbGrp+sfb] == AH_ACTIVE) {
- ahFlag[ch][sfbGrp+sfb] = AH_INACTIVE;
- }
- }
- }
- }
-}
-
-
-static FIXP_DBL CalcRedValPower(FIXP_DBL num,
- FIXP_DBL denum,
- INT* scaling )
-{
- FIXP_DBL value = FL2FXCONST_DBL(0.f);
-
- if (num>=FL2FXCONST_DBL(0.f)) {
- value = fDivNorm( num, denum, scaling);
- }
- else {
- value = -fDivNorm( -num, denum, scaling);
- }
- value = f2Pow(value, *scaling, scaling);
- *scaling = DFRACT_BITS-1-*scaling;
-
- return value;
-}
-
-
-/*****************************************************************************
-functionname: FDKaacEnc_adaptThresholdsToPe
-description: two guesses for the reduction value and one final correction of the thresholds
-*****************************************************************************/
-static void FDKaacEnc_adaptThresholdsToPe(CHANNEL_MAPPING* cm,
- ATS_ELEMENT* AdjThrStateElement[(8)],
- QC_OUT_ELEMENT* qcElement[(8)],
- PSY_OUT_ELEMENT* psyOutElement[(8)],
- const INT desiredPe,
- const INT processElements,
- const INT elementOffset)
-{
- FIXP_DBL redValue[(8)];
- SCHAR redValScaling[(8)];
- UCHAR pAhFlag[(8)][(2)][MAX_GROUPED_SFB];
- FIXP_DBL pThrExp[(8)][(2)][MAX_GROUPED_SFB];
- int iter;
-
- INT constPartGlobal, noRedPeGlobal, nActiveLinesGlobal, redPeGlobal;
- constPartGlobal = noRedPeGlobal = nActiveLinesGlobal = redPeGlobal = 0;
-
- int elementId;
-
- int nElements = elementOffset+processElements;
- if(nElements > cm->nElements) {
- nElements = cm->nElements;
- }
-
- /* ------------------------------------------------------- */
- /* Part I: Initialize data structures and variables... */
- /* ------------------------------------------------------- */
- for (elementId = elementOffset;elementId<nElements;elementId++) {
- if (cm->elInfo[elementId].elType != ID_DSE) {
-
- INT nChannels = cm->elInfo[elementId].nChannelsInEl;
- PE_DATA *peData = &qcElement[elementId]->peData;
-
- /* thresholds to the power of redExp */
- FDKaacEnc_calcThreshExp(pThrExp[elementId], qcElement[elementId]->qcOutChannel, psyOutElement[elementId]->psyOutChannel, nChannels);
-
- /* lower the minSnr requirements for low energies compared to the average
- energy in this frame */
- FDKaacEnc_adaptMinSnr(qcElement[elementId]->qcOutChannel, psyOutElement[elementId]->psyOutChannel, &AdjThrStateElement[elementId]->minSnrAdaptParam, nChannels);
-
- /* init ahFlag (0: no ah necessary, 1: ah possible, 2: ah active */
- FDKaacEnc_initAvoidHoleFlag(qcElement[elementId]->qcOutChannel, psyOutElement[elementId]->psyOutChannel, pAhFlag[elementId], &psyOutElement[elementId]->toolsInfo, nChannels, peData, &AdjThrStateElement[elementId]->ahParam);
-
- /* sum up */
- constPartGlobal += peData->constPart;
- noRedPeGlobal += peData->pe;
- nActiveLinesGlobal += fixMax((INT)peData->nActiveLines, 1);
-
- } /* EOF DSE-suppression */
- } /* EOF for all elements... */
-
- /* ----------------------------------------------------------------------- */
- /* Part II: Calculate bit consumption of initial bit constraints setup */
- /* ----------------------------------------------------------------------- */
- for (elementId = elementOffset;elementId<nElements;elementId++) {
- if (cm->elInfo[elementId].elType != ID_DSE) {
- /*
- redVal = ( 2 ^ ( (constPartGlobal-desiredPe) / (invRedExp*nActiveLinesGlobal) )
- - 2 ^ ( (constPartGlobal-noRedPeGlobal) / (invRedExp*nActiveLinesGlobal) ) )
- */
-
-
- INT nChannels = cm->elInfo[elementId].nChannelsInEl;
- PE_DATA *peData = &qcElement[elementId]->peData;
-
- /* first guess of reduction value */
- int scale0=0, scale1=0;
- FIXP_DBL tmp0 = CalcRedValPower( constPartGlobal-desiredPe, 4*nActiveLinesGlobal, &scale0 );
- FIXP_DBL tmp1 = CalcRedValPower( constPartGlobal-noRedPeGlobal, 4*nActiveLinesGlobal, &scale1 );
-
- int scalMin = FDKmin(scale0, scale1)-1;
-
- redValue[elementId] = scaleValue(tmp0,(scalMin-scale0)) - scaleValue(tmp1,(scalMin-scale1));
- redValScaling[elementId] = scalMin;
-
- /* reduce thresholds */
- FDKaacEnc_reduceThresholdsCBR(qcElement[elementId]->qcOutChannel, psyOutElement[elementId]->psyOutChannel, pAhFlag[elementId], pThrExp[elementId], nChannels, redValue[elementId], redValScaling[elementId]);
-
- /* pe after first guess */
- FDKaacEnc_calcPe(psyOutElement[elementId]->psyOutChannel, qcElement[elementId]->qcOutChannel, peData, nChannels);
-
- redPeGlobal += peData->pe;
- } /* EOF DSE-suppression */
- } /* EOF for all elements... */
-
- /* -------------------------------------------------- */
- /* Part III: Iterate until bit constraints are met */
- /* -------------------------------------------------- */
- iter = 0;
- while ((fixp_abs(redPeGlobal - desiredPe) > fMultI(FL2FXCONST_DBL(0.05f),desiredPe)) && (iter < 1)) {
-
- INT desiredPeNoAHGlobal;
- INT redPeNoAHGlobal = 0;
- INT constPartNoAHGlobal = 0;
- INT nActiveLinesNoAHGlobal = 0;
-
- for (elementId = elementOffset;elementId<nElements;elementId++) {
- if (cm->elInfo[elementId].elType != ID_DSE) {
-
- INT redPeNoAH, constPartNoAH, nActiveLinesNoAH;
- INT nChannels = cm->elInfo[elementId].nChannelsInEl;
- PE_DATA *peData = &qcElement[elementId]->peData;
-
- /* pe for bands where avoid hole is inactive */
- FDKaacEnc_FDKaacEnc_calcPeNoAH(&redPeNoAH, &constPartNoAH, &nActiveLinesNoAH,
- peData, pAhFlag[elementId], psyOutElement[elementId]->psyOutChannel, nChannels);
-
- redPeNoAHGlobal += redPeNoAH;
- constPartNoAHGlobal += constPartNoAH;
- nActiveLinesNoAHGlobal += nActiveLinesNoAH;
- } /* EOF DSE-suppression */
- } /* EOF for all elements... */
-
- /* Calculate new redVal ... */
- if(desiredPe < redPeGlobal) {
-
- /* new desired pe without bands where avoid hole is active */
- desiredPeNoAHGlobal = desiredPe - (redPeGlobal - redPeNoAHGlobal);
-
- /* limit desiredPeNoAH to positive values, as the PE can not become negative */
- desiredPeNoAHGlobal = FDKmax(0,desiredPeNoAHGlobal);
-
- /* second guess (only if there are bands left where avoid hole is inactive)*/
- if (nActiveLinesNoAHGlobal > 0) {
- for (elementId = elementOffset;elementId<nElements;elementId++) {
- if (cm->elInfo[elementId].elType != ID_DSE) {
- /*
- redVal += ( 2 ^ ( (constPartNoAHGlobal-desiredPeNoAHGlobal) / (invRedExp*nActiveLinesNoAHGlobal) )
- - 2 ^ ( (constPartNoAHGlobal-redPeNoAHGlobal) / (invRedExp*nActiveLinesNoAHGlobal) ) )
- */
- int scale0 = 0;
- int scale1 = 0;
-
- FIXP_DBL tmp0 = CalcRedValPower( constPartNoAHGlobal-desiredPeNoAHGlobal, 4*nActiveLinesNoAHGlobal, &scale0 );
- FIXP_DBL tmp1 = CalcRedValPower( constPartNoAHGlobal-redPeNoAHGlobal, 4*nActiveLinesNoAHGlobal, &scale1 );
-
- int scalMin = FDKmin(scale0, scale1)-1;
-
- tmp0 = scaleValue(tmp0,(scalMin-scale0)) - scaleValue(tmp1,(scalMin-scale1));
- scale0 = scalMin;
-
- /* old reduction value */
- tmp1 = redValue[elementId];
- scale1 = redValScaling[elementId];
-
- scalMin = fixMin(scale0,scale1)-1;
-
- /* sum up old and new reduction value */
- redValue[elementId] = scaleValue(tmp0,(scalMin-scale0)) + scaleValue(tmp1,(scalMin-scale1));
- redValScaling[elementId] = scalMin;
-
- } /* EOF DSE-suppression */
- } /* EOF for all elements... */
- } /* nActiveLinesNoAHGlobal > 0 */
- }
- else {
- /* desiredPe >= redPeGlobal */
- for (elementId = elementOffset;elementId<nElements;elementId++) {
- if (cm->elInfo[elementId].elType != ID_DSE) {
-
- INT redVal_scale = 0;
- FIXP_DBL tmp = fDivNorm((FIXP_DBL)redPeGlobal, (FIXP_DBL)desiredPe, &redVal_scale);
-
- /* redVal *= redPeGlobal/desiredPe; */
- redValue[elementId] = fMult(redValue[elementId], tmp);
- redValScaling[elementId] -= redVal_scale;
-
- FDKaacEnc_resetAHFlags(pAhFlag[elementId], cm->elInfo[elementId].nChannelsInEl, psyOutElement[elementId]->psyOutChannel);
- } /* EOF DSE-suppression */
- } /* EOF for all elements... */
- }
-
- redPeGlobal = 0;
- /* Calculate new redVal's PE... */
- for (elementId = elementOffset;elementId<nElements;elementId++) {
- if (cm->elInfo[elementId].elType != ID_DSE) {
-
- INT nChannels = cm->elInfo[elementId].nChannelsInEl;
- PE_DATA *peData = &qcElement[elementId]->peData;
-
- /* reduce thresholds */
- FDKaacEnc_reduceThresholdsCBR(qcElement[elementId]->qcOutChannel, psyOutElement[elementId]->psyOutChannel, pAhFlag[elementId], pThrExp[elementId], nChannels, redValue[elementId], redValScaling[elementId]);
-
- /* pe after second guess */
- FDKaacEnc_calcPe(psyOutElement[elementId]->psyOutChannel, qcElement[elementId]->qcOutChannel, peData, nChannels);
- redPeGlobal += peData->pe;
-
- } /* EOF DSE-suppression */
- } /* EOF for all elements... */
-
- iter++;
- } /* EOF while */
-
-
- /* ------------------------------------------------------- */
- /* Part IV: if still required, further reduce constraints */
- /* ------------------------------------------------------- */
- /* 1.0* 1.15* 1.20*
- * desiredPe desiredPe desiredPe
- * | | |
- * ...XXXXXXXXXXXXXXXXXXXXXXXXXXX| |
- * | | |XXXXXXXXXXX...
- * | |XXXXXXXXXXX|
- * --- A --- | --- B --- | --- C ---
- *
- * (X): redPeGlobal
- * (A): FDKaacEnc_correctThresh()
- * (B): FDKaacEnc_allowMoreHoles()
- * (C): FDKaacEnc_reduceMinSnr()
- */
-
- /* correct thresholds to get closer to the desired pe */
- if ( redPeGlobal > desiredPe ) {
- FDKaacEnc_correctThresh(cm, qcElement, psyOutElement, pAhFlag, pThrExp, redValue, redValScaling,
- desiredPe - redPeGlobal, processElements, elementOffset);
-
- /* update PE */
- redPeGlobal = 0;
- for(elementId=elementOffset;elementId<nElements;elementId++) {
- if (cm->elInfo[elementId].elType != ID_DSE) {
-
- INT nChannels = cm->elInfo[elementId].nChannelsInEl;
- PE_DATA *peData = &qcElement[elementId]->peData;
-
- /* pe after correctThresh */
- FDKaacEnc_calcPe(psyOutElement[elementId]->psyOutChannel, qcElement[elementId]->qcOutChannel, peData, nChannels);
- redPeGlobal += peData->pe;
-
- } /* EOF DSE-suppression */
- } /* EOF for all elements... */
- }
-
- if ( redPeGlobal > desiredPe ) {
- /* reduce pe by reducing minSnr requirements */
- FDKaacEnc_reduceMinSnr(cm, qcElement, psyOutElement, pAhFlag,
- (fMultI(FL2FXCONST_DBL(0.15f),desiredPe) + desiredPe),
- &redPeGlobal, processElements, elementOffset);
-
- /* reduce pe by allowing additional spectral holes */
- FDKaacEnc_allowMoreHoles(cm, qcElement, psyOutElement, AdjThrStateElement, pAhFlag,
- desiredPe, redPeGlobal, processElements, elementOffset);
- }
-
-}
-
-/* similar to FDKaacEnc_adaptThresholdsToPe(), for VBR-mode */
-void FDKaacEnc_AdaptThresholdsVBR(QC_OUT_CHANNEL* qcOutChannel[(2)],
- PSY_OUT_CHANNEL* psyOutChannel[(2)],
- ATS_ELEMENT* AdjThrStateElement,
- struct TOOLSINFO *toolsInfo,
- PE_DATA *peData,
- const INT nChannels)
-{
- UCHAR (*pAhFlag)[MAX_GROUPED_SFB];
- FIXP_DBL (*pThrExp)[MAX_GROUPED_SFB];
-
- /* allocate scratch memory */
- C_ALLOC_SCRATCH_START(_pAhFlag, UCHAR, (2)*MAX_GROUPED_SFB)
- C_ALLOC_SCRATCH_START(_pThrExp, FIXP_DBL, (2)*MAX_GROUPED_SFB)
- pAhFlag = (UCHAR(*)[MAX_GROUPED_SFB])_pAhFlag;
- pThrExp = (FIXP_DBL(*)[MAX_GROUPED_SFB])_pThrExp;
-
- /* thresholds to the power of redExp */
- FDKaacEnc_calcThreshExp(pThrExp, qcOutChannel, psyOutChannel, nChannels);
-
- /* lower the minSnr requirements for low energies compared to the average
- energy in this frame */
- FDKaacEnc_adaptMinSnr(qcOutChannel, psyOutChannel, &AdjThrStateElement->minSnrAdaptParam, nChannels);
-
- /* init ahFlag (0: no ah necessary, 1: ah possible, 2: ah active */
- FDKaacEnc_initAvoidHoleFlag(qcOutChannel, psyOutChannel, pAhFlag, toolsInfo,
- nChannels, peData, &AdjThrStateElement->ahParam);
-
- /* reduce thresholds */
- FDKaacEnc_reduceThresholdsVBR(qcOutChannel, psyOutChannel, pAhFlag, pThrExp, nChannels,
- AdjThrStateElement->vbrQualFactor,
- &AdjThrStateElement->chaosMeasureOld);
-
- /* free scratch memory */
- C_ALLOC_SCRATCH_END(_pThrExp, FIXP_DBL, (2)*MAX_GROUPED_SFB)
- C_ALLOC_SCRATCH_END(_pAhFlag, UCHAR, (2)*MAX_GROUPED_SFB)
-}
-
-
-/*****************************************************************************
-
- functionname: FDKaacEnc_calcBitSave
- description: Calculates percentage of bit save, see figure below
- returns:
- input: parameters and bitres-fullness
- output: percentage of bit save
-
-*****************************************************************************/
-/*
- bitsave
- maxBitSave(%)| clipLow
- |---\
- | \
- | \
- | \
- | \
- |--------\--------------> bitres
- | \
- minBitSave(%)| \------------
- clipHigh maxBitres
-*/
-static FIXP_DBL FDKaacEnc_calcBitSave(FIXP_DBL fillLevel,
- const FIXP_DBL clipLow,
- const FIXP_DBL clipHigh,
- const FIXP_DBL minBitSave,
- const FIXP_DBL maxBitSave,
- const FIXP_DBL bitsave_slope)
-{
- FIXP_DBL bitsave;
-
- fillLevel = fixMax(fillLevel, clipLow);
- fillLevel = fixMin(fillLevel, clipHigh);
-
- bitsave = maxBitSave - fMult((fillLevel-clipLow), bitsave_slope);
-
- return (bitsave);
-}
-
-/*****************************************************************************
-
- functionname: FDKaacEnc_calcBitSpend
- description: Calculates percentage of bit spend, see figure below
- returns:
- input: parameters and bitres-fullness
- output: percentage of bit spend
-
-*****************************************************************************/
-/*
- bitspend clipHigh
- maxBitSpend(%)| /-----------maxBitres
- | /
- | /
- | /
- | /
- | /
- |----/-----------------> bitres
- | /
- minBitSpend(%)|--/
- clipLow
-*/
-static FIXP_DBL FDKaacEnc_calcBitSpend(FIXP_DBL fillLevel,
- const FIXP_DBL clipLow,
- const FIXP_DBL clipHigh,
- const FIXP_DBL minBitSpend,
- const FIXP_DBL maxBitSpend,
- const FIXP_DBL bitspend_slope)
-{
- FIXP_DBL bitspend;
-
- fillLevel = fixMax(fillLevel, clipLow);
- fillLevel = fixMin(fillLevel, clipHigh);
-
- bitspend = minBitSpend + fMult(fillLevel-clipLow, bitspend_slope);
-
- return (bitspend);
-}
-
-
-/*****************************************************************************
-
- functionname: FDKaacEnc_adjustPeMinMax()
- description: adjusts peMin and peMax parameters over time
- returns:
- input: current pe, peMin, peMax, bitres size
- output: adjusted peMin/peMax
-
-*****************************************************************************/
-static void FDKaacEnc_adjustPeMinMax(const INT currPe,
- INT *peMin,
- INT *peMax)
-{
- FIXP_DBL minFacHi = FL2FXCONST_DBL(0.3f), maxFacHi = (FIXP_DBL)MAXVAL_DBL, minFacLo = FL2FXCONST_DBL(0.14f), maxFacLo = FL2FXCONST_DBL(0.07f);
- INT diff;
-
- INT minDiff_fix = fMultI(FL2FXCONST_DBL(0.1666666667f), currPe);
-
- if (currPe > *peMax)
- {
- diff = (currPe-*peMax) ;
- *peMin += fMultI(minFacHi,diff);
- *peMax += fMultI(maxFacHi,diff);
- }
- else if (currPe < *peMin)
- {
- diff = (*peMin-currPe) ;
- *peMin -= fMultI(minFacLo,diff);
- *peMax -= fMultI(maxFacLo,diff);
- }
- else
- {
- *peMin += fMultI(minFacHi, (currPe - *peMin));
- *peMax -= fMultI(maxFacLo, (*peMax - currPe));
- }
-
- if ((*peMax - *peMin) < minDiff_fix)
- {
- INT peMax_fix = *peMax, peMin_fix = *peMin;
- FIXP_DBL partLo_fix, partHi_fix;
-
- partLo_fix = (FIXP_DBL)fixMax(0, currPe - peMin_fix);
- partHi_fix = (FIXP_DBL)fixMax(0, peMax_fix - currPe);
-
- peMax_fix = (INT)(currPe + fMultI(fDivNorm(partHi_fix, (partLo_fix+partHi_fix)), minDiff_fix));
- peMin_fix = (INT)(currPe - fMultI(fDivNorm(partLo_fix, (partLo_fix+partHi_fix)), minDiff_fix));
- peMin_fix = fixMax(0, peMin_fix);
-
- *peMax = peMax_fix;
- *peMin = peMin_fix;
- }
-}
-
-
-
-/*****************************************************************************
-
- functionname: BitresCalcBitFac
- description: calculates factor of spending bits for one frame
- 1.0 : take all frame dynpart bits
- >1.0 : take all frame dynpart bits + bitres
- <1.0 : put bits in bitreservoir
- returns: BitFac
- input: bitres-fullness, pe, blockType, parameter-settings
- output:
-
-*****************************************************************************/
-/*
- bitfac(%) pemax
- bitspend(%) | /-----------maxBitres
- | /
- | /
- | /
- | /
- | /
- |----/-----------------> pe
- | /
- bitsave(%) |--/
- pemin
-*/
-
-static FIXP_DBL FDKaacEnc_bitresCalcBitFac(const INT bitresBits,
- const INT maxBitresBits,
- const INT pe,
- const INT lastWindowSequence,
- const INT avgBits,
- const FIXP_DBL maxBitFac,
- ADJ_THR_STATE *AdjThr,
- ATS_ELEMENT *adjThrChan)
-{
- BRES_PARAM *bresParam;
- INT pex;
-
- INT qmin, qbr, qbres, qmbr;
- FIXP_DBL bitSave, bitSpend;
-
- FIXP_DBL bitresFac_fix, tmp_cst, tmp_fix;
- FIXP_DBL pe_pers, bits_ratio, maxBrVal;
- FIXP_DBL bitsave_slope, bitspend_slope, maxBitFac_tmp;
- FIXP_DBL fillLevel_fix = (FIXP_DBL)0x7fffffff;
- FIXP_DBL UNITY = (FIXP_DBL)0x7fffffff;
- FIXP_DBL POINT7 = (FIXP_DBL)0x5999999A;
-
- if (maxBitresBits > bitresBits) {
- fillLevel_fix = fDivNorm(bitresBits, maxBitresBits);
- }
-
- if (lastWindowSequence != SHORT_WINDOW)
- {
- bresParam = &(AdjThr->bresParamLong);
- bitsave_slope = (FIXP_DBL)0x3BBBBBBC;
- bitspend_slope = (FIXP_DBL)0x55555555;
- }
- else
- {
- bresParam = &(AdjThr->bresParamShort);
- bitsave_slope = (FIXP_DBL)0x2E8BA2E9;
- bitspend_slope = (FIXP_DBL)0x7fffffff;
- }
-
- pex = fixMax(pe, adjThrChan->peMin);
- pex = fixMin(pex, adjThrChan->peMax);
-
- bitSave = FDKaacEnc_calcBitSave(fillLevel_fix,
- bresParam->clipSaveLow, bresParam->clipSaveHigh,
- bresParam->minBitSave, bresParam->maxBitSave, bitsave_slope);
-
- bitSpend = FDKaacEnc_calcBitSpend(fillLevel_fix,
- bresParam->clipSpendLow, bresParam->clipSpendHigh,
- bresParam->minBitSpend, bresParam->maxBitSpend, bitspend_slope);
-
- pe_pers = fDivNorm(pex - adjThrChan->peMin, adjThrChan->peMax - adjThrChan->peMin);
- tmp_fix = fMult(((FIXP_DBL)bitSpend + (FIXP_DBL)bitSave), pe_pers);
- bitresFac_fix = (UNITY>>1) - ((FIXP_DBL)bitSave>>1) + (tmp_fix>>1); qbres = (DFRACT_BITS-2);
-
- /* (float)bitresBits/(float)avgBits */
- bits_ratio = fDivNorm(bitresBits, avgBits, &qbr);
- qbr = DFRACT_BITS-1-qbr;
-
- /* Add 0.7 in q31 to bits_ratio in qbr */
- /* 0.7f + (float)bitresBits/(float)avgBits */
- qmin = fixMin(qbr, (DFRACT_BITS-1));
- bits_ratio = bits_ratio >> (qbr - qmin);
- tmp_cst = POINT7 >> ((DFRACT_BITS-1) - qmin);
- maxBrVal = (bits_ratio>>1) + (tmp_cst>>1); qmbr = qmin - 1;
-
- /* bitresFac_fix = fixMin(bitresFac_fix, 0.7 + bitresBits/avgBits); */
- bitresFac_fix = bitresFac_fix >> (qbres - qmbr); qbres = qmbr;
- bitresFac_fix = fixMin(bitresFac_fix, maxBrVal);
-
- /* Compare with maxBitFac */
- qmin = fixMin(Q_BITFAC, qbres);
- bitresFac_fix = bitresFac_fix >> (qbres - qmin);
- maxBitFac_tmp = maxBitFac >> (Q_BITFAC - qmin);
- if(maxBitFac_tmp < bitresFac_fix)
- {
- bitresFac_fix = maxBitFac;
- }
- else
- {
- if(qmin < Q_BITFAC)
- {
- bitresFac_fix = bitresFac_fix << (Q_BITFAC-qmin);
- }
- else
- {
- bitresFac_fix = bitresFac_fix >> (qmin-Q_BITFAC);
- }
- }
-
- FDKaacEnc_adjustPeMinMax(pe, &adjThrChan->peMin, &adjThrChan->peMax);
-
- return bitresFac_fix;
-}
-
-
-/*****************************************************************************
-functionname: FDKaacEnc_AdjThrNew
-description: allocate ADJ_THR_STATE
-*****************************************************************************/
-INT FDKaacEnc_AdjThrNew(ADJ_THR_STATE** phAdjThr,
- INT nElements)
-{
- INT err = 0;
- INT i;
- ADJ_THR_STATE* hAdjThr = GetRam_aacEnc_AdjustThreshold();
- if (hAdjThr==NULL) {
- err = 1;
- goto bail;
- }
-
- for (i=0; i<nElements; i++) {
- hAdjThr->adjThrStateElem[i] = GetRam_aacEnc_AdjThrStateElement(i);
- if (hAdjThr->adjThrStateElem[i]==NULL) {
- err = 1;
- goto bail;
- }
- }
-
-bail:
- *phAdjThr = hAdjThr;
- return err;
-}
-
-
-/*****************************************************************************
-functionname: FDKaacEnc_AdjThrInit
-description: initialize ADJ_THR_STATE
-*****************************************************************************/
-void FDKaacEnc_AdjThrInit(
- ADJ_THR_STATE *hAdjThr,
- const INT meanPe,
- ELEMENT_BITS *elBits[(8)],
- INT invQuant,
- INT nElements,
- INT nChannelsEff,
- INT sampleRate,
- INT advancedBitsToPe,
- FIXP_DBL vbrQualFactor
- )
-{
- INT i;
-
- FIXP_DBL POINT8 = FL2FXCONST_DBL(0.8f);
- FIXP_DBL POINT6 = FL2FXCONST_DBL(0.6f);
-
- /* common for all elements: */
- /* parameters for bitres control */
- hAdjThr->bresParamLong.clipSaveLow = (FIXP_DBL)0x1999999a; /* FL2FXCONST_DBL(0.2f); */
- hAdjThr->bresParamLong.clipSaveHigh = (FIXP_DBL)0x7999999a; /* FL2FXCONST_DBL(0.95f); */
- hAdjThr->bresParamLong.minBitSave = (FIXP_DBL)0xf999999a; /* FL2FXCONST_DBL(-0.05f); */
- hAdjThr->bresParamLong.maxBitSave = (FIXP_DBL)0x26666666; /* FL2FXCONST_DBL(0.3f); */
- hAdjThr->bresParamLong.clipSpendLow = (FIXP_DBL)0x1999999a; /* FL2FXCONST_DBL(0.2f); */
- hAdjThr->bresParamLong.clipSpendHigh = (FIXP_DBL)0x7999999a; /* FL2FXCONST_DBL(0.95f); */
- hAdjThr->bresParamLong.minBitSpend = (FIXP_DBL)0xf3333333; /* FL2FXCONST_DBL(-0.10f); */
- hAdjThr->bresParamLong.maxBitSpend = (FIXP_DBL)0x33333333; /* FL2FXCONST_DBL(0.4f); */
-
- hAdjThr->bresParamShort.clipSaveLow = (FIXP_DBL)0x199999a0; /* FL2FXCONST_DBL(0.2f); */
- hAdjThr->bresParamShort.clipSaveHigh = (FIXP_DBL)0x5fffffff; /* FL2FXCONST_DBL(0.75f); */
- hAdjThr->bresParamShort.minBitSave = (FIXP_DBL)0x00000000; /* FL2FXCONST_DBL(0.0f); */
- hAdjThr->bresParamShort.maxBitSave = (FIXP_DBL)0x199999a0; /* FL2FXCONST_DBL(0.2f); */
- hAdjThr->bresParamShort.clipSpendLow = (FIXP_DBL)0x199999a0; /* FL2FXCONST_DBL(0.2f); */
- hAdjThr->bresParamShort.clipSpendHigh = (FIXP_DBL)0x5fffffff; /* FL2FXCONST_DBL(0.75f); */
- hAdjThr->bresParamShort.minBitSpend = (FIXP_DBL)0xf9999998; /* FL2FXCONST_DBL(-0.05f); */
- hAdjThr->bresParamShort.maxBitSpend = (FIXP_DBL)0x40000000; /* FL2FXCONST_DBL(0.5f); */
-
- /* specific for each element: */
- for (i=0; i<nElements; i++) {
- ATS_ELEMENT* atsElem = hAdjThr->adjThrStateElem[i];
- MINSNR_ADAPT_PARAM *msaParam = &atsElem->minSnrAdaptParam;
- INT chBitrate = elBits[i]->chBitrateEl;
-
- /* parameters for bitres control */
- atsElem->peMin = fMultI(POINT8, meanPe) >> 1;
- atsElem->peMax = fMultI(POINT6, meanPe);
-
- /* for use in FDKaacEnc_reduceThresholdsVBR */
- atsElem->chaosMeasureOld = FL2FXCONST_DBL(0.3f);
-
- /* additional pe offset to correct pe2bits for low bitrates */
- atsElem->peOffset = 0;
-
- /* vbr initialisation */
- atsElem->vbrQualFactor = vbrQualFactor;
- if (chBitrate < 32000)
- {
- atsElem->peOffset = fixMax(50, 100-fMultI((FIXP_DBL)0x666667, chBitrate));
- }
-
- /* avoid hole parameters */
- if (chBitrate > 20000) {
- atsElem->ahParam.modifyMinSnr = TRUE;
- atsElem->ahParam.startSfbL = 15;
- atsElem->ahParam.startSfbS = 3;
- }
- else {
- atsElem->ahParam.modifyMinSnr = FALSE;
- atsElem->ahParam.startSfbL = 0;
- atsElem->ahParam.startSfbS = 0;
- }
-
- /* minSnr adaptation */
- msaParam->maxRed = FL2FXCONST_DBL(0.00390625f); /* 0.25f/64.0f */
- /* start adaptation of minSnr for avgEn/sfbEn > startRatio */
- msaParam->startRatio = FL2FXCONST_DBL(0.05190512648f); /* ld64(10.0f) */
- /* maximum minSnr reduction to minSnr^maxRed is reached for
- avgEn/sfbEn >= maxRatio */
- /* msaParam->maxRatio = 1000.0f; */
- /*msaParam->redRatioFac = ((float)1.0f - msaParam->maxRed) / ((float)10.0f*log10(msaParam->startRatio/msaParam->maxRatio)/log10(2.0f)*(float)0.3010299956f);*/
- msaParam->redRatioFac = FL2FXCONST_DBL(-0.375f); /* -0.0375f * 10.0f */
- /*msaParam->redOffs = (float)1.0f - msaParam->redRatioFac * (float)10.0f * log10(msaParam->startRatio)/log10(2.0f) * (float)0.3010299956f;*/
- msaParam->redOffs = FL2FXCONST_DBL(0.021484375); /* 1.375f/64.0f */
-
- /* init pe correction */
- atsElem->peCorrectionFactor_m = FL2FXCONST_DBL(0.5f); /* 1.0 */
- atsElem->peCorrectionFactor_e = 1;
-
- atsElem->dynBitsLast = -1;
- atsElem->peLast = 0;
-
- /* init bits to pe factor */
-
- /* init bits2PeFactor */
- FDKaacEnc_InitBits2PeFactor(
- &atsElem->bits2PeFactor_m,
- &atsElem->bits2PeFactor_e,
- chBitrate, /* bitrate/channel*/
- nChannelsEff, /* number of channels */
- sampleRate,
- advancedBitsToPe,
- invQuant
- );
-
- } /* for nElements */
-
-}
-
-
-/*****************************************************************************
- functionname: FDKaacEnc_FDKaacEnc_calcPeCorrection
- description: calc desired pe
-*****************************************************************************/
-static void FDKaacEnc_FDKaacEnc_calcPeCorrection(
- FIXP_DBL *const correctionFac_m,
- INT *const correctionFac_e,
- const INT peAct,
- const INT peLast,
- const INT bitsLast,
- const FIXP_DBL bits2PeFactor_m,
- const INT bits2PeFactor_e
- )
-{
- if ( (bitsLast > 0) && (peAct < 1.5f*peLast) && (peAct > 0.7f*peLast) &&
- (FDKaacEnc_bits2pe2(bitsLast, fMult(FL2FXCONST_DBL(1.2f/2.f), bits2PeFactor_m), bits2PeFactor_e+1) > peLast) &&
- (FDKaacEnc_bits2pe2(bitsLast, fMult(FL2FXCONST_DBL(0.65f), bits2PeFactor_m), bits2PeFactor_e ) < peLast) )
- {
- FIXP_DBL corrFac = *correctionFac_m;
-
- int scaling = 0;
- FIXP_DBL denum = (FIXP_DBL)FDKaacEnc_bits2pe2(bitsLast, bits2PeFactor_m, bits2PeFactor_e);
- FIXP_DBL newFac = fDivNorm((FIXP_DBL)peLast, denum, &scaling);
-
- /* dead zone, newFac and corrFac are scaled by 0.5 */
- if ((FIXP_DBL)peLast <= denum) { /* ratio <= 1.f */
- newFac = fixMax(scaleValue(fixMin( fMult(FL2FXCONST_DBL(1.1f/2.f), newFac), scaleValue(FL2FXCONST_DBL( 1.f/2.f), -scaling)), scaling), FL2FXCONST_DBL(0.85f/2.f) );
- }
- else { /* ratio < 1.f */
- newFac = fixMax( fixMin( scaleValue(fMult(FL2FXCONST_DBL(0.9f/2.f), newFac), scaling), FL2FXCONST_DBL(1.15f/2.f) ), FL2FXCONST_DBL( 1.f/2.f) );
- }
-
- if ( ((newFac > FL2FXCONST_DBL(1.f/2.f)) && (corrFac < FL2FXCONST_DBL(1.f/2.f)))
- || ((newFac < FL2FXCONST_DBL(1.f/2.f)) && (corrFac > FL2FXCONST_DBL(1.f/2.f))))
- {
- corrFac = FL2FXCONST_DBL(1.f/2.f);
- }
-
- /* faster adaptation towards 1.0, slower in the other direction */
- if ( (corrFac < FL2FXCONST_DBL(1.f/2.f) && newFac < corrFac)
- || (corrFac > FL2FXCONST_DBL(1.f/2.f) && newFac > corrFac) )
- {
- corrFac = fMult(FL2FXCONST_DBL(0.85f), corrFac) + fMult(FL2FXCONST_DBL(0.15f), newFac);
- }
- else {
- corrFac = fMult(FL2FXCONST_DBL(0.7f), corrFac) + fMult(FL2FXCONST_DBL(0.3f), newFac);
- }
-
- corrFac = fixMax( fixMin( corrFac, FL2FXCONST_DBL(1.15f/2.f) ), FL2FXCONST_DBL(0.85/2.f) );
-
- *correctionFac_m = corrFac;
- *correctionFac_e = 1;
- }
- else {
- *correctionFac_m = FL2FXCONST_DBL(1.f/2.f);
- *correctionFac_e = 1;
- }
-}
-
-
-static void FDKaacEnc_calcPeCorrectionLowBitRes(
- FIXP_DBL *const correctionFac_m,
- INT *const correctionFac_e,
- const INT peLast,
- const INT bitsLast,
- const INT bitresLevel,
- const INT nChannels,
- const FIXP_DBL bits2PeFactor_m,
- const INT bits2PeFactor_e
- )
-{
- /* tuning params */
- const FIXP_DBL amp = FL2FXCONST_DBL(0.005);
- const FIXP_DBL maxDiff = FL2FXCONST_DBL(0.25f);
-
- if (bitsLast > 0) {
-
- /* Estimate deviation of granted and used dynamic bits in previous frame, in PE units */
- const int bitsBalLast = peLast - FDKaacEnc_bits2pe2(
- bitsLast,
- bits2PeFactor_m,
- bits2PeFactor_e);
-
- /* reserve n bits per channel */
- int headroom = (bitresLevel>=50*nChannels) ? 0 : (100*nChannels);
-
- /* in PE units */
- headroom = FDKaacEnc_bits2pe2(
- headroom,
- bits2PeFactor_m,
- bits2PeFactor_e);
-
- /*
- * diff = amp * ((bitsBalLast - headroom) / (bitresLevel + headroom)
- * diff = max ( min ( diff, maxDiff, -maxDiff)) / 2
- */
- FIXP_DBL denominator = (FIXP_DBL)FDKaacEnc_bits2pe2(bitresLevel, bits2PeFactor_m, bits2PeFactor_e) + (FIXP_DBL)headroom;
-
- int scaling = 0;
- FIXP_DBL diff = (bitsBalLast>=headroom)
- ? fMult(amp, fDivNorm( (FIXP_DBL)(bitsBalLast - headroom), denominator, &scaling))
- : -fMult(amp, fDivNorm(-(FIXP_DBL)(bitsBalLast - headroom), denominator, &scaling)) ;
-
- scaling -= 1; /* divide by 2 */
-
- diff = (scaling<=0) ? FDKmax( FDKmin (diff>>(-scaling), maxDiff>>1), -maxDiff>>1)
- : FDKmax( FDKmin (diff, maxDiff>>(1+scaling)), -maxDiff>>(1+scaling)) << scaling;
-
- /*
- * corrFac += diff
- * corrFac = max ( min ( corrFac/2.f, 1.f/2.f, 0.75f/2.f ) )
- */
- *correctionFac_m = FDKmax(FDKmin((*correctionFac_m)+diff, FL2FXCONST_DBL(1.0f/2.f)), FL2FXCONST_DBL(0.75f/2.f)) ;
- *correctionFac_e = 1;
- }
- else {
- *correctionFac_m = FL2FXCONST_DBL(0.75/2.f);
- *correctionFac_e = 1;
- }
-}
-
-void FDKaacEnc_DistributeBits(ADJ_THR_STATE *adjThrState,
- ATS_ELEMENT *AdjThrStateElement,
- PSY_OUT_CHANNEL *psyOutChannel[(2)],
- PE_DATA *peData,
- INT *grantedPe,
- INT *grantedPeCorr,
- const INT nChannels,
- const INT commonWindow,
- const INT grantedDynBits,
- const INT bitresBits,
- const INT maxBitresBits,
- const FIXP_DBL maxBitFac,
- const INT bitDistributionMode)
-{
- FIXP_DBL bitFactor;
- INT noRedPe = peData->pe;
-
- /* prefer short windows for calculation of bitFactor */
- INT curWindowSequence = LONG_WINDOW;
- if (nChannels==2) {
- if ((psyOutChannel[0]->lastWindowSequence == SHORT_WINDOW) ||
- (psyOutChannel[1]->lastWindowSequence == SHORT_WINDOW)) {
- curWindowSequence = SHORT_WINDOW;
- }
- }
- else {
- curWindowSequence = psyOutChannel[0]->lastWindowSequence;
- }
-
- if (grantedDynBits >= 1) {
- if (bitDistributionMode!=0) {
- *grantedPe = FDKaacEnc_bits2pe2(grantedDynBits, AdjThrStateElement->bits2PeFactor_m, AdjThrStateElement->bits2PeFactor_e);
- }
- else
- {
- /* factor dependend on current fill level and pe */
- bitFactor = FDKaacEnc_bitresCalcBitFac(bitresBits, maxBitresBits, noRedPe,
- curWindowSequence, grantedDynBits, maxBitFac,
- adjThrState,
- AdjThrStateElement
- );
-
- /* desired pe for actual frame */
- /* Worst case max of grantedDynBits is = 1024 * 5.27 * 2 */
- *grantedPe = FDKaacEnc_bits2pe2(grantedDynBits,
- fMult(bitFactor, AdjThrStateElement->bits2PeFactor_m), AdjThrStateElement->bits2PeFactor_e+(DFRACT_BITS-1-Q_BITFAC)
- );
- }
- }
- else {
- *grantedPe = 0; /* prevent divsion by 0 */
- }
-
- /* correction of pe value */
- switch (bitDistributionMode) {
- case 2:
- case 1:
- FDKaacEnc_calcPeCorrectionLowBitRes(
- &AdjThrStateElement->peCorrectionFactor_m,
- &AdjThrStateElement->peCorrectionFactor_e,
- AdjThrStateElement->peLast,
- AdjThrStateElement->dynBitsLast,
- bitresBits,
- nChannels,
- AdjThrStateElement->bits2PeFactor_m,
- AdjThrStateElement->bits2PeFactor_e
- );
- break;
- case 0:
- default:
- FDKaacEnc_FDKaacEnc_calcPeCorrection(
- &AdjThrStateElement->peCorrectionFactor_m,
- &AdjThrStateElement->peCorrectionFactor_e,
- fixMin(*grantedPe, noRedPe),
- AdjThrStateElement->peLast,
- AdjThrStateElement->dynBitsLast,
- AdjThrStateElement->bits2PeFactor_m,
- AdjThrStateElement->bits2PeFactor_e
- );
- break;
- }
-
- *grantedPeCorr = (INT)(fMult((FIXP_DBL)(*grantedPe<<Q_AVGBITS), AdjThrStateElement->peCorrectionFactor_m) >> (Q_AVGBITS-AdjThrStateElement->peCorrectionFactor_e));
-
- /* update last pe */
- AdjThrStateElement->peLast = *grantedPe;
- AdjThrStateElement->dynBitsLast = -1;
-
-}
-
-/*****************************************************************************
-functionname: FDKaacEnc_AdjustThresholds
-description: adjust thresholds
-*****************************************************************************/
-void FDKaacEnc_AdjustThresholds(ATS_ELEMENT* AdjThrStateElement[(8)],
- QC_OUT_ELEMENT* qcElement[(8)],
- QC_OUT* qcOut,
- PSY_OUT_ELEMENT* psyOutElement[(8)],
- INT CBRbitrateMode,
- CHANNEL_MAPPING* cm)
-{
- int i;
- if (CBRbitrateMode)
- {
- /* In case, no bits must be shifted between different elements, */
- /* an element-wise execution of the pe-dependent threshold- */
- /* adaption becomes necessary... */
- for (i=0; i<cm->nElements; i++)
- {
- ELEMENT_INFO elInfo = cm->elInfo[i];
-
- if ((elInfo.elType == ID_SCE) || (elInfo.elType == ID_CPE) ||
- (elInfo.elType == ID_LFE))
- {
- /* qcElement[i]->grantedPe = 2000; */ /* Use this only for debugging */
- //if (totalGrantedPeCorr < totalNoRedPe) {
- if (qcElement[i]->grantedPe < qcElement[i]->peData.pe)
- {
- /* calc threshold necessary for desired pe */
- FDKaacEnc_adaptThresholdsToPe(cm,
- AdjThrStateElement,
- qcElement,
- psyOutElement,
- qcElement[i]->grantedPeCorr,
- 1, /* Process only 1 element */
- i); /* Process exactly THIS element */
-
- }
-
- } /* -end- if(ID_SCE || ID_CPE || ID_LFE) */
-
- } /* -end- element loop */
- }
- else {
- for (i=0; i<cm->nElements; i++)
- {
- ELEMENT_INFO elInfo = cm->elInfo[i];
-
- if ((elInfo.elType == ID_SCE) || (elInfo.elType == ID_CPE) ||
- (elInfo.elType == ID_LFE))
- {
- /* for VBR-mode */
- FDKaacEnc_AdaptThresholdsVBR(qcElement[i]->qcOutChannel,
- psyOutElement[i]->psyOutChannel,
- AdjThrStateElement[i],
- &psyOutElement[i]->toolsInfo,
- &qcElement[i]->peData,
- cm->elInfo[i].nChannelsInEl);
- } /* -end- if(ID_SCE || ID_CPE || ID_LFE) */
-
- } /* -end- element loop */
-
- }
- for (i=0; i<cm->nElements; i++) {
- int ch,sfb,sfbGrp;
- /* no weighting of threholds and energies for mlout */
- /* weight energies and thresholds */
- for (ch=0; ch<cm->elInfo[i].nChannelsInEl; ch++) {
- QC_OUT_CHANNEL* pQcOutCh = qcElement[i]->qcOutChannel[ch];
- for (sfbGrp = 0;sfbGrp < psyOutElement[i]->psyOutChannel[ch]->sfbCnt; sfbGrp+=psyOutElement[i]->psyOutChannel[ch]->sfbPerGroup) {
- for (sfb=0; sfb<psyOutElement[i]->psyOutChannel[ch]->maxSfbPerGroup; sfb++) {
- pQcOutCh->sfbThresholdLdData[sfb+sfbGrp] += pQcOutCh->sfbEnFacLd[sfb+sfbGrp];
- }
- }
- }
- }
-}
-
-void FDKaacEnc_AdjThrClose(ADJ_THR_STATE** phAdjThr)
-{
- INT i;
- ADJ_THR_STATE* hAdjThr = *phAdjThr;
-
- if (hAdjThr!=NULL) {
- for (i=0; i<(8); i++) {
- if (hAdjThr->adjThrStateElem[i]!=NULL) {
- FreeRam_aacEnc_AdjThrStateElement(&hAdjThr->adjThrStateElem[i]);
- }
- }
- FreeRam_aacEnc_AdjustThreshold(phAdjThr);
- }
-}
-